The present invention includes a pipette stand having a base, a trunk extending from the base, and a holding assembly coupled to the trunk. The holding assembly forms one or more apertures configured to receive at least a portion of a pipette therein, and the one or more apertures define a first width. The pipette stand also includes an insert removably couplable to the holding assembly and configured to modify the first width.

A temperature control device for controlling a temperature of a substance to obtain a first temperature and to change to a second temperature has first and second heating blocks and a heating device. The heating device heats the first and second heating blocks to the first and second temperatures, respectively. The temperature control device has a first material opposing the first heating block to define a first space between them arranged to receive the substance and to define a first temperature zone having substantially the first temperature. The temperature control device has a second material opposing the second heating block such as to define a second space between them arranged to receive the substance and define a second temperature zone having substantially the second temperature, the first and second spaces being arranged such that the substance can be moved from the first temperature zone to the second temperature zone.

A component for a storage container configured to receive vertically oriented articles. The component includes a tubular sidewall extending longitudinally from a base, and at least one spacer portion extending from an underside of the base and configured for engagement with an interior surface of a corresponding storage container. The component also includes at least one pair of retainer elements extending laterally from an inner surface of the tubular sidewall and inwardly into an interior region of the component, and with the retainer elements being oppositely oriented and configured to retain a vertically oriented article therebetween by frictional engagement with opposite longitudinal edges of the article, and wherein an insertion force for resilient deflection of the retainer elements during insertion of the article is less than a removal force for resilient deflection of the retainer elements during removal of the article.

A laboratory apparatus comprising a housing, wherein the housing comprises a through-opening, wherein the through-opening is adapted for passing through it a transport device for transporting laboratory sample containers in and/or out of the housing, and a cover, wherein the cover comprises at least two ring segments, wherein the ring segments are adjustable to each other between a distant adjustment with at least one distance in between ends of the ring segments for arranging them around the passed through transport device and a near adjustment with less or no distance in between the ends of the ring segments for surrounding the passed through transport device, and wherein the cover in the near adjustment is adapted to cover a part of the through-opening left free by the passed through transport device, wherein the laboratory apparatus is a pre-analytical, analytical, and/or post-analytical laboratory apparatus, in particular a sorting module.

A component for a storage container configured to receive vertically oriented articles. The component includes a tubular sidewall extending longitudinally from a base, and at least one spacer portion extending from an underside of the base and configured for engagement with an interior surface of a corresponding storage container. The component also includes at least one pair of retainer elements extending laterally from an inner surface of the tubular sidewall and inwardly into an interior region of the component, and with the retainer elements being oppositely oriented and configured to retain a vertically oriented article therebetween by frictional engagement with opposite longitudinal edges of the article, and wherein an insertion force for resilient deflection of the retainer elements during insertion of the article is less than a removal force for resilient deflection of the retainer elements during removal of the article.

An embodiment of the invention relates to systems and methods for detecting the orientation of sample carriers using two or more RFID tags. One or two dimensional matrix of equally spaced RFID reader antennas may be positioned beneath or within an area on which racks are placed. The first RFID tag defines the origin of the sample carrier and its geometry. The second and additional RFID tags define the orientations of the sample carrier relative to the matrix of the RFID reader antennas. At least two of the tag antennas on the rack align uniquely with two antennas on the reader matrix. The system energizes each reader antenna and associates the RFID tags aligned with them to the RFID reader antenna's physical position.

An instrument and a method for the automated thermal treatment of liquid samples are disclosed. An inter-distance between a temperature-controlled receptacle for loading with a plurality of vessels for containing the samples and end portions of optical fibers can be varied, wherein the receptacle is configured to form a thermal communication with the loaded vessels and wherein the optical fibers have first and second end portions. The first end portion and the second end portion of each optical fiber is fixed with respect to each other for transmitting light, wherein the variation of the in-ter-distance allows the vessels to be loaded to or unloaded from the receptacle and to enable detection of light from the samples contained in the one or more receptacle-loaded vessels.

A component for a storage container configured to receive vertically oriented articles. The component includes a tubular sidewall extending longitudinally from a base, and at least one spacer portion extending from an underside of the base and configured for engagement with an interior surface of a corresponding storage container. The component also includes at least one pair of retainer elements extending laterally from an inner surface of the tubular sidewall and inwardly into an interior region of the component, and with the retainer elements being oppositely oriented and configured to retain a vertically oriented article therebetween by frictional engagement with opposite longitudinal edges of the article, and wherein an insertion force for resilient deflection of the retainer elements during insertion of the article is less than a removal force for resilient deflection of the retainer elements during removal of the article.

The present invention includes a pipette stand having a base, a trunk extending from the base, and a holding assembly coupled to the trunk. The holding assembly forms one or more apertures configured to receive at least a portion of a pipette therein, and the one or more apertures define a first width. The pipette stand also includes an insert removably couplable to the holding assembly and configured to modify the first width.

An embodiment of the invention relates to systems and methods for detecting the orientation of sample carriers using two or more RFID tags. One or two dimensional matrix of equally spaced RFID reader antennas may be positioned beneath or within an area on which racks are placed. The first RFID tag defines the origin of the sample carrier and its geometry. The second and additional RFID tags define the orientations of the sample carrier relative to the matrix of the RFID reader antennas. At least two of the tag antennas on the rack align uniquely with two antennas on the reader matrix. The system energizes each reader antenna and associates the RFID tags aligned with them to the RFID reader antenna's physical position.