A filter cartridge assembly for an ice making appliance having a rectilinear filter cartridge with a plurality of partitions that are positioned within an internal chamber, form multiple sub-chambers, and create a non-linear pathway for the flow of water through the filter cartridge. Filter media positioned in the sub-chambers of the filter cartridge are configured to remove dissolved solids from water travelling through the filter cartridge and used by the appliance to create ice, including clear ice.

A filter cartridge assembly for an ice making appliance having a rectilinear filter cartridge with a plurality of partitions that are positioned within an internal chamber, form multiple sub-chambers, and create a non-linear pathway for the flow of water through the filter cartridge. Filter media positioned in the sub-chambers of the filter cartridge are configured to remove dissolved solids from water travelling through the filter cartridge and used by the appliance to create ice, including clear ice.

The present disclosure pertains to sample preparation devices useful for affinity capture and purification that include one or more internal structures that comprise a reservoir, a well, a fluid passageway, sorbent particles, and a filter element that blocks passage of the affinity sorbent particles, which sample preparation devices combine the attributes of both dispersive and flow through designs into a single sample preparation device. The present disclosure also pertains to kits that contain and methods that use such sample preparation devices.

The present disclosure pertains to sample preparation devices useful for affinity capture and purification that include one or more internal structures that comprise a reservoir, a well, a fluid passageway, sorbent particles, and a filter element that blocks passage of the affinity sorbent particles, which sample preparation devices combine the attributes of both dispersive and flow through designs into a single sample preparation device. The present disclosure also pertains to kits that contain and methods that use such sample preparation devices.

A cartridge for an e-vaping device includes a reservoir configured to hold pre-vapor formulation, a vaporizer assembly configured to draw at least some of the pre-vapor formulation from the reservoir and vaporize the drawn pre-vapor formulation to form a vapor, and a superabsorbent polymer configured to absorb free water from pre-vapor formulation held in the reservoir. The superabsorbent polymer includes a cross-linked polyacrylate copolymer that is substantially inert to the pre-vapor formulation. The superabsorbent polymer may be included in a layer on one or more surfaces in the cartridge. The layer may include the superabsorbent polymer and a binder. The superabsorbent polymer may be included with the pre-vapor formulation in a formulation mixture. The superabsorbent polymer may be included in an interior of at least one element comprising the cartridge. The superabsorbent polymer may be included in a separate compartment in the reservoir.

A cartridge for an e-vaping device includes a reservoir configured to hold pre-vapor formulation, a vaporizer assembly configured to draw at least some of the pre-vapor formulation from the reservoir and vaporize the drawn pre-vapor formulation to form a vapor, and a superabsorbent polymer configured to absorb free water from pre-vapor formulation held in the reservoir. The superabsorbent polymer includes a cross-linked polyacrylate copolymer that is substantially inert to the pre-vapor formulation. The superabsorbent polymer may be included in a layer on one or more surfaces in the cartridge. The layer may include the superabsorbent polymer and a binder. The superabsorbent polymer may be included with the pre-vapor formulation in a formulation mixture. The superabsorbent polymer may be included in an interior of at least one element comprising the cartridge. The superabsorbent polymer may be included in a separate compartment in the reservoir.

A multi-walled tube that is useful as an analytical column in which chemical mixtures can be separated into their individual components is described. In order to be acceptable as an analytical column, the inner surface of the multi-walled tube must support effective separation, but not react chemically with or contaminate the solvent or the analyte (sample to be separated). Grade 316 stainless steel is typically preferred for this purpose. Moreover, the inner diameter (ID) surface of the multi-walled column is preferably very smooth (less than 10 micro inch Ra) with no interruptions in the surface such as scratches, pits, or asperities. However, since the column is designed to be attached to chromatographic equipment using standard size connection features, the size of standard fittings define the outer diameter (OD) of the column.

A multi-walled tube that is useful as an analytical column in which chemical mixtures can be separated into their individual components is described. In order to be acceptable as an analytical column, the inner surface of the multi-walled tube must support effective separation, but not react chemically with or contaminate the solvent or the analyte (sample to be separated). Grade 316 stainless steel is typically preferred for this purpose. Moreover, the inner diameter (ID) surface of the multi-walled column is preferably very smooth (less than 10 micro inch Ra) with no interruptions in the surface such as scratches, pits, or asperities. However, since the column is designed to be attached to chromatographic equipment using standard size connection features, the size of standard fittings define the outer diameter (OD) of the column.

A liquid chromatography column, utilizing horizontal or radial flow of sample material passing there through, includes a housing defining a chamber therein, at least one removable screw lid, and first and second longitudinally extending porous frits positioned within the chamber. A bed or packing of particulate, chromatographic separation material is positioned within the chamber and intermediate the porous frits, the first of the porous frits being adjacent the housing and an inlet channel, the second of the porous frits being positioned adjacent a core member and an outlet channel. A distributor is operatively connected to the inlet channel, and a collector is connected to the outlet channel. The distributor and the inlet channel are constructed to direct associated material to be separated in the bed evenly across a longitudinal length of the bed in a horizontal direction.

A liquid chromatography column, utilizing horizontal or radial flow of sample material passing there through, includes a housing defining a chamber therein, at least one removable screw lid, and first and second longitudinally extending porous frits positioned within the chamber. A bed or packing of particulate, chromatographic separation material is positioned within the chamber and intermediate the porous frits, the first of the porous frits being adjacent the housing and an inlet channel, the second of the porous frits being positioned adjacent a core member and an outlet channel. A distributor is operatively connected to the inlet channel, and a collector is connected to the outlet channel. The distributor and the inlet channel are constructed to direct associated material to be separated in the bed evenly across a longitudinal length of the bed in a horizontal direction.