The present disclosure relates to a cuvette box conveying device, a cuvette box conveying method, and a sample analyzer. The cuvette box conveying device includes a frame. The frame includes a new box placing position and a waste box recycling position. The new box placing position and the waste box recycling position are arranged on different layers in the direction of Z axis, so as to reduce the space occupied by the new box placing position and the waste box recycling position on an XY plane. In the cuvette box conveying device, the space occupied by the new box placing position and the waste box recycling position on the XY plane is reduced by arranging the new box placing position and the waste box recycling position on different layers in the direction of Z axis.

The present disclosure relates to a cuvette box conveying device, a cuvette box conveying method, and a sample analyzer. The cuvette box conveying device includes a frame. The frame includes a new box placing position and a waste box recycling position. The new box placing position and the waste box recycling position are arranged on different layers in the direction of Z axis, so as to reduce the space occupied by the new box placing position and the waste box recycling position on an XY plane. In the cuvette box conveying device, the space occupied by the new box placing position and the waste box recycling position on the XY plane is reduced by arranging the new box placing position and the waste box recycling position on different layers in the direction of Z axis.

The purpose of the present invention is to provide a highly reliable specimen carrier device with which it is possible to position a specimen holder in a specific place with high accuracy, thereby enabling the stable performance of a treatment. In order to achieve this purpose, the present invention provides a specimen carrier device that is equipped with: a specimen holder which retains a specimen container and which is equipped with a magnetic body; and a first positioning means which is disposed beneath a carrier surface and which conveys and stops the specimen holder by attracting and repelling the magnetic body, wherein a second positioning means for pressing the specimen holder or the specimen container is provided on the carrier surface.

The purpose of the present invention is to provide a highly reliable specimen carrier device with which it is possible to position a specimen holder in a specific place with high accuracy, thereby enabling the stable performance of a treatment. In order to achieve this purpose, the present invention provides a specimen carrier device that is equipped with: a specimen holder which retains a specimen container and which is equipped with a magnetic body; and a first positioning means which is disposed beneath a carrier surface and which conveys and stops the specimen holder by attracting and repelling the magnetic body, wherein a second positioning means for pressing the specimen holder or the specimen container is provided on the carrier surface.

A device for receiving, stacking, and removing microplates is presented and described. The device comprises a tower for stacking the microplates, wherein a microplate comprises a container and, optionally, a lid. There is a retaining device at the lower end of the tower, which has a first retaining tool and a second retaining tool, and preferably partially encompasses a microplate. The first retaining tool is designed to hold a microplate in a form-fitting manner. The second retaining tool is designed to fix a container in the microplate in place in a frictional manner. The first retaining tool is above the second retaining tool in the stacking direction. A system that comprises the device described above, a dispenser device, and a transport device, is also disclosed. The dispenser device is used to fill microplates, and the transport device is used to add and remove microplates to and from the device.

Example automated diagnostic analyzers and methods for using the same are disclosed herein. An example apparatus described herein includes a first carousel rotatably coupled to a base and having a first axis of rotation. The example apparatus includes a second carousel rotatably coupled to the base and vertically spaced over the first carousel such that at least a portion of the second carousel is disposed over the first carousel. In the example apparatus, the second carousel has a second axis of rotation and a plurality of vessels. The example apparatus also includes a pipetting mechanism offset from the second axis of rotation. The example pipetting mechanism is to access the first carousel and the second carousel.

Example automated diagnostic analyzers and methods for using the same are disclosed herein. An example apparatus described herein includes a first carousel rotatably coupled to a base and having a first axis of rotation. The example apparatus includes a second carousel rotatably coupled to the base and vertically spaced over the first carousel such that at least a portion of the second carousel is disposed over the first carousel. In the example apparatus, the second carousel has a second axis of rotation and a plurality of vessels. The example apparatus also includes a pipetting mechanism offset from the second axis of rotation. The example pipetting mechanism is to access the first carousel and the second carousel.

A biological material measuring instrument is described. The biological material measuring instrument includes a rotating body and a main body. The rotating body includes one or more cartridge holders having cuvettes in which a reagent and an analyte in a sample react. The main body includes a pair of light-emitting parts and light-receiving parts to optically measure the analyte in the sample. The rotating body further includes a light-emitting optical waveguide for guiding the light of the light-emitting parts to the cuvette and a light-receiving optical waveguide for guiding.

A biological material measuring instrument is described. The biological material measuring instrument includes a rotating body and a main body. The rotating body includes one or more cartridge holders having cuvettes in which a reagent and an analyte in a sample react. The main body includes a pair of light-emitting parts and light-receiving parts to optically measure the analyte in the sample. The rotating body further includes a light-emitting optical waveguide for guiding the light of the light-emitting parts to the cuvette and a light-receiving optical waveguide for guiding.

An automated method for sampling seeds generally includes removing material from a seed at an automated sampling station and then, after removing the material from the seed, detecting, by at least one sensor, movement of the seed out of the automated sampling station. The automated method may also include, after removing the material from the seed, transferring the seed from the automated sampling station to a seed container and transferring the material removed from the seed from the automated sampling station to a sample container.