A sample processing system is configured for analyzing, preprocessing, or carrying out other operations for a biological sample such as blood or urea. With the sample processing system, it is possible to store samples to be stored in a thermally insulated state or specimens required for accuracy control in the thermally insulated state for preventing evaporation or denaturing of the samples and specimens. Also it is possible to carry in or out the samples, rack by rack, according to necessity. Further, the sample processing system is provided with a buffer unit in a cold container having a capability for cold storage and also by accessing a sample rack at random for carrying in or out a rack with a transfer mechanism provided outside of the cold container.

Disclosed is a sample measurement device comprising a first processing unit that performs a first measurement on a sample contained in a first container in a first cycle; a second processing unit that performs a second measurement on a sample contained in a second container in a second cycle different from the first cycle; and a relay section which is disposed between the first processing unit and the second processing unit and in which the second container is positioned, wherein the first processing unit performs a transferring operation of transferring the second container to the relay section, and the second processing unit performs a receiving operation of receiving the second container that has been transferred to the relay section from the relay section.

Example automated storage modules for analyzer liquids are described herein. An example apparatus includes a refrigerated storage module having a plurality of shelves (to store a plurality of carriers) and a loading bay having an array of slots to receive one or more of the carriers. The loading bay is accessible by a user for manual loading or unloading of the carriers. The example apparatus includes a first carrier transporter coupled to the storage module to transfer the carriers between the shelves and a first transfer location and a second carrier transporter movable along a track connecting the storage module to an automated diagnostic analyzer. The second carrier transporter is to transfer a first carrier between the first transfer location and a slot in the loading bay and a second carrier between the first transfer location and a second transfer location accessible by the automated diagnostic analyzer.

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.

This automated analysis device is provided with a plurality of analysis units for analyzing a specimen, a buffer portion which holds a plurality of specimen racks on which are placed specimen containers holding the specimen, a sampler portion which conveys the specimen racks held in the buffer portion to the analysis units, and a control portion which, when performing a process to deliver the specimen racks to the plurality of analysis units, outputs synchronization signals to all the plurality of analysis units, wherein the analysis unit performs a delivery process starting from the synchronization signal, and the analysis unit performs a delivery process starting from the synchronization signal.

An automated analyzer is provided with one or more dispensing lines 109, 209 that are each for loading and unloading, at one end thereof, a sample rack 101 having placed therein one or more sample containers accommodating a sample for analysis and for conveying the sample rack back and forth from a dispensing position for dispensing the sample from the sample containers and sample rack removal parts 111, 211 that are provided adjacent to the other ends of the dispensing lines 109, 209 and provide and receive sample racks to and from the dispensing lines 109, 209. According to this configuration, it is possible to convey an urgent sample while suppressing device complexity, preventing cost from increasing, and also maintaining speed.

A sample examination automation system that allows reducing a delay of conveyance due to a stop of supply of empty sample carriers without disposing a conveyance line for empty sample carrier is provided. The sample examination automation system includes a conveyance line, a large-scale sample carrier buffer, an analyzer coupling unit, and a conveyance managing unit. The conveyance line conveys a sample carrier. One or a plurality of sample containers is mountable on the sample carrier. The large-scale sample carrier buffer stores a plurality of the sample carriers. The analyzer coupling unit is couplable to an analyzer. The analyzer coupling unit incorporates a sample carrier sub-buffer. The sample carrier sub-buffer is capable of storing the sample carriers by an amount smaller than an amount of the large-scale sample carrier buffer. The conveyance managing unit has a function of controlling a sample carrier conveyance destination. The conveyance managing unit is configured to determine an amount of the sample carriers supplied to the sample carrier sub-buffer via the large-scale sample carrier buffer according to a storage situation of the sample carriers in the sample carrier sub-buffer.

A sample measurement system includes: a measurement unit that measures a sample stored in a sample container; a transport unit that transports a rack capable of holding sample containers via the measurement unit; a first transport-in/transport-out unit and a second transport-in/transport-out unit in each of which racks can be set alongside in a first direction, and that send the set racks to be transported to the measurement unit and receive the racks transported from the measurement unit; and a controller that controls the first transport-in/transport-out unit and the second transport-in/transport-out unit so that the racks are sequentially sent from the first transport-in/transport-out unit and the second transport-in/transport-out unit. The first transport-in/transport-out unit and the second transport-in/transport-out unit are disposed alongside in a second direction crossing the first direction, and each send the racks from one side in the first direction, and receive the racks from the other side.

Provided is a specimen processing system which can contribute to space saving. The specimen processing system includes a put-in module which puts a specimen on a put-in tray in a holder, a housing module which houses the specimen from the holder in a housing tray, and a stock module which stocks the holder, in which an empty holder which is generated because the specimen is housed is directly conveyed to the put-in module without being conveyed to the stock module and is used for putting a new specimen therein.

In blood coagulation time measurement, the reaction time relies on the blood coagulation ability of a specimen and is not fixed. In particular, in module-type devices, errors may occur in the specimen processing, measurement number, and measurement time between a plurality of blood coagulation analysis units, leading to the risk of lowering the processing capability of the device as a whole. The present invention is a module-type automated analyzer provided with a plurality of blood coagulation analysis units capable of analyzing blood coagulation time items in which the reaction time between a specimen and a reagent differs depending on the specimen, wherein a control unit that controls the specimen rack conveying operation finds the total of forecasted measurement times of measurement items requested for specimens being analyzed and queued specimens in each of the plurality of blood coagulation analysis units, and determines the conveyance destination of the specimen rack on the basis of the total of the forecasted measurement times that was found.