A method for measuring optical signal detector performance that includes directing light emitted from an optical signal detector onto a first non-fluorescent surface portion in a first detection zone of the optical signal detector. A first characteristic of light detected by a first sensor of the first optical signal detector is measured while the first non-fluorescent surface portion is in the first detection zone of the optical signal detector. Light emitted from the optical signal detector is directed into a first void in the first detection zone of the optical signal detector. A second characteristic of light detected by the first sensor of the optical signal detector is measured while the first void is in the first detection zone of the optical signal detector. And an operational performance status of the optical signal detector is determined based on at least one of the first characteristic and the second characteristic.

A digital slide scanning apparatus slide rack carousel allows continuous loading and unloading of slide racks into the carousel while the digital slide scanning apparatus is simultaneously digitizing glass slides. The slide rack carousel includes a base having an interior portion of its upper surface at an angle. The slide rack carousel also includes plural rack spacers extending upward from the base and adjacent rack spacers define a rack slot. Each rack spacer also includes a rack stopper on each side such that adjacent rack spacers have rack stoppers facing each other. The rack stoppers prevent a slide rack from moving further toward the center of the carousel than desired.

An apparatus for conveying a plurality of articles includes a transport belt, a bumper stopper, and a rotator. A motor moves the transport belt which is adapted to rotate the rotator as the belt conveys the plurality of articles. The stopper can move between first and second positions relative to the transport belt wherein the bumper stopper guides one article toward the rotator when the bumper stopper is in the first position. The bumper stopper allows the article to be conveyed to another location when the bumper stopper is in the second position. The transport belt can continue to convey other articles while the one article is temporarily held in place by the bumper stopper. The rotator is configured to rotate the article conveyed by the transport belt. The article can remain in contact with the transport belt while the rotator is rotating the article.

A conveying device includes a carrier which includes a holder side member; a conveying passage which guides conveyance of the carrier; a spirally-shaped spiral member which is arranged below the carrier and extends along the conveying passage, the spiral member causing between the spiral member and the holder side member a first force which acts in a direction away from the holder side member or a second force which acts to draw in the holder side member; a partition wall portion which is provided between the carrier and the spiral member and partitions the carrier and the spiral member; and a rotary unit which rotates the spiral member axis-wise thereof.

A sample rack transport apparatus for transporting a sample rack to a sample analyser, comprising: a bidirectional transmission track for bidirectionally transmitting a sample rack without passing through the sample analyser; a feed channel in parallel with the bidirectional transmission track, wherein the sample rack may be delivered from the bidirectional transmission track to the feed channel and to the sample analyser; an unloading cache region located between the bidirectional transmission track and the feed channel, the unloading cache region being used for storing the sample tack; and an unloading mechanism for delivering the sample rack in the feed channel to the unloading cache region for storage, or delivering the sample rack stored in the unloading cache region to the bidirectional transmission track. Also provided are a sample analysis device and a sample analysis system using the sample rack transport apparatus.

Apparatus for a cotton sample acquisition and tracking system. The system includes a loading station in which a pair of primary sample halves are loaded in a carrier. The primary samples are identified and transported to a sub-sample station that extracts a sub-sample from the primary sample. The sub-samples are conditioned and transported to various testing stations. The primary samples are transported via a conveyor system. The sub-samples are transported through a pneumatic system. The sub-sample station advances the primary sample against a pick drum that pulls tufts from the primary sample. The tufts flow through a cotton containment system into an indexer that collects, conditions, and routes the tufts as a sub-sample. The sub-samples are staged in a carousel for continued conditioning and storage until the test equipment is ready to process the sub-sample.

A vertical conveying device for the transport of sample container carriers having sample tubes received therein between a bottom level and a top level of a sample distribution system is presented. The vertical conveying device comprises a plurality of conveying surfaces which are movable along a circulating path. A sample distribution system having such a vertical conveying device and to a laboratory automation system having such a sample distribution system are also presented.

Disclosed are high-throughput vessel supply systems and methods of supplying sample vessels, such as samples stored in test tubes. A system for supplying a plurality of individual vessels that each contains a sample is disclosed.

Described is a testing system for performing specimen testing, such as residual seal force (RSF) testing and/or compression friction (CF) measurement testing. The testing system comprising a column supported by a base structure, a load cell supported by said column, a specimen plate configured to receive a plurality of specimens, a motor, and controller. The load cell is configured to move along the column toward and away from the base structure via a crosshead coupled to an actuator. The plurality of specimens comprising a first specimen and a second specimen. The controller is configured to control the motor to adjust a position of said specimen plate.

A sample rack moving mechanism is provided for removing a sample rack loaded with one or more sample containers from a temporary storing section, and returning the sample rack loaded with the sample containers holding the tested sample to the temporary storing section. The sample rack moving mechanism may include a drive element, a cam driven by the drive element to rotate and having a curve contour, a cam follower moving following the outer contour of the cam, a guide groove corresponding to the temporary storing section, having a bottom plane of the same height as a support plane of the temporary storing section for supporting the sample rack, and capable of moving the sample rack, and a support element driven by the cam follower to move upward and downward and driving the sample rack to horizontally move between the temporary storing section and the guide groove.