A sample measurement system and method of transporting of racks are provided that collectively supply the consumables to the sample measurement units. The sample measurement system includes: sample measurement units that perform measurement on samples by using consumables; a setting part in which a user sets consumable racks housing the consumables; a first transport path that supplies the consumable racks set in the setting part to one of the sample measurement units; a collector that is arranged adjacent to the setting part and that collects empty racks that are emptied after being transported to at least one of the sample measurement units; and a second transport path that transports the empty racks to the collector.

The present invention is provided with a sample rack insertion unit 12 that is capable of holding one or more sample racks 5 having mounted therein one or more sample containers 6 accommodating a sample to be analyzed, one or more analysis devices 2, 3 for analyzing the sample accommodated in the sample containers 6, a sample rack conveyance unit 14 for conveying the sample racks 5 from the sample rack insertion unit 12 to the analysis devices 2, 3, and a control device 4 for acquiring, for each analysis device 2, 3, load information that is information expressing an operating condition of the analysis device 2, 3, and, if there is an analysis device 2, 3 for which the load information is larger than a predetermined conveyance permission value, carrying out control so as to stop the conveyance of the sample racks 5 from the sample rack insertion unit 12 to the analysis device(s) 2, 3. As a result of this configuration, it is possible to mitigate in-device sample conveyance congestion occurring as a result of the insertion of many samples and keep the sample environment and analysis processing power at high levels.

Embodiments in accordance with the present disclosure are directed to apparatuses used for reaction screening and optimization purposes. An example apparatus includes a plurality of reaction vessels, a dispensing subsystem, at least one reactor module, an analysis subsystem, an automation subsystem, and control circuitry. The dispensing subsystem delivers reagents to the plurality of reaction vessels for a plurality of reaction mixtures having varied reaction conditions. The at least one reactor module drives a plurality of reactions within the plurality of reaction vessels. The analysis subsystem analyzes compositions contained in the plurality of reaction vessels. The automation subsystem selectively moves the plurality of reaction vessels from a location proximal to the dispensing subsystem to the at least one reactor module based on experimental design parameters. And, the control circuitry identifies optimum reaction conditions for a target end product based on the analysis.

An automatic analysis device has a structure that allows the operator to add or replace a reagent. A reagent container loading portion has an opening through which a reagent container is adapted to be introduced into the device. A reagent container transport tool has a plurality of reagent container insertion slots and is movable up and down. A refrigerator to cool a plurality of reagent containers has an opening that allows the reagent container transport tool to pass therethrough. An elevating and lowering mechanism is configured to elevate or lower the reagent container transport tool. A reagent container loading portion has a plurality of guide grooves arranged radially on its lower surface in front of the opening that are adapted to guide a reagent container. The guide grooves communicate with the respective reagent container insertion slots arranged radially on the reagent container transport tool at an elevated position.

Disclosed is a detachable modularized test platform. The detachable modularized test platform includes a gantry, a control box and a jig box, where a test area is arranged on the jig box, an air cylinder is arranged on the gantry, a control assembly is mounted in the control box, and a test assembly is mounted in the jig box; during testing, a sample to be tested is placed on the test area, and the upper computer sends an instruction to control the air cylinder to extend a driving rod to move to the sample to be tested; and the upper computer sends the instruction to the control assembly in the control box, to complete testing of the sample, and output and upload test data to a server for saving. The present invention employs a modularized structure, which reduces a size, detection is convenient, and applicability is high.

The apparatus contains a driving unit having a driving source device and a driving shaft, and the driving shaft has a drive-side roller for rotating the object (specimen container). The driving shaft is provided with a one-directional transmission device containing a mechanism for transmitting only rotational driving force in the first direction of the driving shaft to a driven-side part. The apparatus has a mechanism for converting a rotational driving force in the first direction to move a driving unit in a direction away from the object or a mechanism for converting a rotational driving force in the first direction to move a driven unit in a direction away from the object, and the rotational driving force in the second direction of the driving shaft rotates the object.

A solvent storage device and a liquid transfer system. The solvent storage device is provided with at least one layer of a frame which has a receiving chamber with an opening. A container carrying assembly for carrying containers is arranged in, and the container carrying assembly is provided with a plurality of container placement parts. The container carrying assembly is connected to the frame through a first moving mechanism for driving the container carrying assembly to move in a straight line at the opening. Accordingly, the space occupied by a plurality of containers can be reduced and the liquid transfer operation is more convenient.

To provide a container disposal unit that enables disposal of a reaction container without clogging and includes a disposal unit having a simple structure and a small dead space, an automatic analyzer having the container disposal unit, and a method for discarding a reaction container used in the automatic analyzer. A reaction container disposal unit includes a reaction container disposal hole arranged on a back side of an automatic analyzer to discard a used reaction container 116a, a disposal box arranged on a front side of the automatic analyzer to temporarily store the used reaction container 116a, and an inclined part configured to connect the container disposal hole on the back side to an upper side of the disposal box on the front side so as to introduce the reaction container 116a into the disposal box.

A laboratory sample distribution system comprising a transport plane and a cleaning device for cleaning the transport plane is presented. The cleaning device is adapted to automatically clean the transport plane similar to sample container carriers moving also on the transport plane. A laboratory automation system comprising such a laboratory sample distribution system is also presented.

An automated instrument for processing a sample includes a first lock configured to move between a locked configuration and an unlocked configuration. The first lock is configured to be engaged with a first movable holding structure in the locked configuration to secure the first holding structure within the automated instrument. The first lock is configured to be disengaged from the first holding structure in the unlocked configuration to allow movement of the first holding structure within the automated instrument. The automated instrument also includes a robotic arm movable within the automated instrument and configured to move the first lock between the locked configuration and the unlocked configuration. The first holding structure is configured to hold a sample processing device and configured to move within the automated instrument when the first lock is in the unlocked configuration. The robotic arm can also be configured to move the sample processing device within the system.