The present disclosure relates to methodologies, systems, apparatus, and kits for introducing a sample within a chromatography system. A makeup pump is configured to pump a makeup fluid through a first restrictor into the chromatography system upstream of the column and downstream of a mobile phase pump. The first restrictor is located upstream of a column and downstream of makeup pump and a sample fluid pump. Decreasing an output volume of the makeup pump can direct a sample fluid from the sample fluid pump through the first restrictor to the column. Increasing an output volume of the makeup pump can direct the sample fluid to a second restrictor located downstream of the makeup pump and in parallel with the column and the detector.

A fluid distributor unit comprising a channel system where one or more inlet channels (2) starting on an inlet side (3) of the distributor unit branch out successively into several channels (6) ending on the other side of the distributor unit, called the outlet side (4), characterised in that said distributor unit is provided in one single body (1) by free form fabrication.

In a preparative separation-purification system for passing a solution containing a target component through a trap column 21 to capture the target component in the column 21, and for subsequently passing an eluting solvent through the column 21 to elute the captured component and collect it in a container, an outlet aperture 27 of the column 21 has a tapered shape whose sectional area is largest on a plane facing an inner space of the column 21 and decreases in the flowing direction of the liquid. A filter 26 for preventing deposition of the target component is also provided at the boundary between the inner space of the column 21 and a passage for discharging liquid from the inner space. By this configuration, clogging of the passage at the outlet end of the column 21 due to deposition of the target component is prevented.

A column mainly comprises a tube, a plug, a first filter, a second filter, a stopper, and a connector. The tube mainly comprises a bottomed cylindrical storage part, and a cylindrical bottom-side connection part connected to a bottom of the storage part. The storage part and the bottom-side connection part are coaxially provided. The plug mainly comprises an outer pipe coaxially provided, and an inner pipe provided on an inner side of the outer pipe. The first filter and the second filter each are such a filter as not to enable the filler to pass. The stopper mainly comprises a stopper gripping part, and a stopper insertion part. The connector mainly comprises a connector gripping part and a connector insertion part.

A container for treating a fluid with an ion-exchange system is provided. The container includes a housing extending in an upright position between a bottom port and an opposed top port. The housing has an internal chamber. A bottom plate is disposed in the internal chamber above the bottom port and having a plurality of openings defined therethrough. The bottom plate divides the internal chamber between a main chamber and a bottom chamber. The bottom chamber is defined between the bottom plate and the bottom port. A plurality of diffusers extend from the bottom plate into the main chamber. Each one of the plurality of diffusers has a diffuser tube section projecting upwardly from the bottom plate and in fluid flow communication with the bottom chamber. The diffuser tube section has radial openings circumferentially distributed along a length thereof to radially discharge the fluid in the main chamber.

The present invention relates to axial flow chromatography columns, methods for separating one or more analytes in a liquid by the use of such columns, and systems employing such columns. The column comprises a first port and a second port, the first port and said second port being at essentially the same level or elevation above the level of the bed space on the chromatography column.

A separation column for expanded bed adsorption comprises a column tube (2), a base (15) carrying an inlet rotor structure (6) for pumping in process liquid, and a top cap (3). The top cap (3) is conical in form, and has a peripheral flange 31 by which it is rigidly fixed to the top edge flange (22) of the column tube (2). The angle of the convergent interior surface (35) of the conical top cap (3) may be between 10 and 25°. A vortex-inhibitor component (8) projects down below the outlet structure (4) at the top of the cap, projecting into the operating space (15) of the column to inhibit rotation of liquid in the column interior. An expanded bed adsorption process is done with upward flow of liquid in the column through a bed of media particles.

The present invention relates to axial flow chromatography columns, methods for separating one or more analytes in a liquid by the use of such columns, and systems employing such columns. The column comprises a first port and a second port the first port and said second port being at essentially the same level or elevation above the level of the bed space on the chromatography column.

A system to thermally desorb a sample into a multi-column GC or GCMS system that can use both the desorption system and GC system for optimizing injection rates, matrix management (e.g., water elimination), optimizing recovery of a specific range of chemicals, and system cleanup is described. Reversing the flow through a first column inside the GC can facilitate the elimination of excess, condensed water as well as heavy chemicals that could otherwise affect the operation and background of the GC. The elimination of flow through both the thermal desorber and a first column in the GC during sample preheat can accommodate the pre-expansion of the sample that could otherwise result in pre-release to the active carrier gas flow in other systems. Transfer lines and rotary valves can be avoided, improving system performance and longevity, with simple maintenance achieved by replacing a desorption liner and the first GC column.

A chromatography device for removing a solute from a fluid is described herein. The device includes a first plate having an inlet, a first primary channel fluidly coupled to the inlet and a first set of secondary channels fluidly coupled to the first primary channel. The device also includes a middle frame housing chromatographic media and a second plate having an outlet, a second primary channel fluidly coupled to the outlet and a first set of secondary channels fluidly coupled to the second primary channel. The first set of secondary channels directs the fluid in a direction that is transverse to a direction of flow of the fluid through the chromatographic media and the second set of secondary channels directs the fluid to the outlet in a direction that is transverse to the direction of flow of the fluid through the chromatographic media.