A gas chromatograph that includes a metering chamber, two separating devices and a multiport valve unit having switching functions for metering, straight separation, cutting and backflush, where the multiport valve unit is formed as a multiport diaphragm valve.

Disclosed is an organic carbon detector that can be used with a liquid chromatography equipment such as a size exclusion chromatography. The organic carbon detector contains a carbon oxidization subsystem and a stripping and CO.sub.2 detection subsystem arranged and detachably connected with each other in said order. The carbon oxidization subsystem contains a microfluidic agent injection module (1), an inorganic carbon removal module (2), a microfluidic ultraviolet oxidation module (3) and a vacuum pumping system (4), configured to remove inorganic carbons and oxidize organic carbons. The stripping and CO.sub.2 detection subsystem contains a stripping module (7) and a CO.sub.2 detector (12), using a carrier gas to transfer the organic carbon converted gas to the CO.sub.2 detector (12). Also disclosed is a method of using the organic carbon detector in water quality monitoring.

A gas analyzer system (100, 200, 300) and methods of reducing sample carryover in a gas sample selector (102, 202, 302). The gas analyzer system (100, 200, 300) includes a gas chromatograph (104, 204, 304) and a gas sample selector (102, 202, 302). The gas sample selector (102, 202, 302) includes a multi-position selector valve (130, 230, 330), a flush valve (140, 240, 340), and a purge valve (150, 250, 350), as well as conduits providing flowpaths between them. When switching the flush valve (140, 240, 340) to connect the flush valve (140, 240, 340) vent and flush valve (140, 240, 340) outlet and flowing purge gas through the purge valve (150, 250, 350) port, the purge gas will flow to the selector (102, 202, 302) exit and to the flush valve (140, 240, 340) vent to remove sample gas from the flowpaths.

A gas component detection device includes a column, a sensor, a flow path, and a flow path switch. The column separates a component of gas to be detected. The sensor is, for example, a semiconductor sensor, is connected to the downstream side of the column, and detects a component of gas to be detected. The flow path connects the column and the sensor. The flow path switch is arranged between a flow path and a flow path. The flow path switch switches between and executes a measurement mode in which gas to be detected discharged from the column flows into the sensor, and a discharge mode in which gas to be detected discharged from the column is discharged to the outside.

A liquid chromatographic (LC) system is herein disclosed, the LC system comprising at least one fluidic stream comprising at least one HPLC column, a downstream valve connected to the at least one fluidic stream and connectable to a detector via a valve-to-detector conduit, wherein the at least one fluidic stream is connectable to the valve-to-detector conduit via the downstream valve, and where the LC system further comprises a downstream pump fluidically connected to the downstream valve and connectable to the at least one fluidic stream via the downstream valve in order to backflush and thereby clean the at least one HPLC column. A respective automated LC method is herein also disclosed.

A sample analysis cup assembly, system and method for purging including a cell body, including a top end; a bottom end; a cell body wall extending axially from the top end to the bottom end; a transverse wall adjacent the top end, including a plurality of apertures extending therethrough; and a raised portion on the transverse wall including a central aperture extending therethrough; a rotatable cap, including a top surface; a bottom surface; and a series of apertures extending from the top surface through the bottom surface, the rotatable cap being structured to engage with the top end of the cell body; and a ring member structured to couple with the bottom end of the cell body are provided.

The disclosed system and method improve measurement of trace volatile chemicals, such as by Gas Chromatography (GC) and Gas Chromatography/Mass Spectrometry (GCMS). A first trapping system can include a plurality of capillary columns in series and a focusing column fluidly coupled to a first detector. The first trapping system can retain and separate compounds in a sample, including C3 hydrocarbons and compounds heavier than C3 hydrocarbons (e.g., up to C12 hydrocarbons, or compounds having a boiling point around 250° C.), and can transfer the compounds from the focusing column to the first detector. A second trapping system can receive compounds that the first trapping system does not retain, and can include a packed trap, a polar column and a PLOT column fluidly coupled to one or more second detectors. The second trapping system can remove water from the sample and can separate and detect compounds including C2 hydrocarbons and Formaldehyde.

A method and system for sample analysis involve a temporally-resolving separation of sample components. In the method, solvent vapors are condensed prior to entering a temporally-resolving separator, a GC column, for example, and solvent-depleted vapors are directed to the separator where constituents are resolved in time. A system for analyzing a sample comprises an injection port, a temporally-resolving separator (e.g., a GC column) and a conduit connecting the two. The injection port is at a temperature sufficiently high to vaporize the solvent and analytes present in a sample. The conduit is configured and/or operated to condense the solvent, while maintaining the analytes in the vapor phase.

Described are a fluidic network and a method for aseptic process sampling. The fluidic network includes a sampling valve, filter, manifold and valve control module. A process sample path in the fluidic network includes one or more valve channels and a filter in fluidic communication with the sampling valve. The sampling valve is configurable in a first valve state to receive a process sample into the process sample path from a process source and configurable in a second valve state in which gas and solvent flows may be provided through the process sample path to clean and dry the process sample path to prepare for acquisition of another process sample.

A sample injection device is provided with a syringe for injecting a sample and an arrangement unit in which plural kinds of cleaning solvents are arranged to clean the syringe. The device is configured to be able to set a cleaning order of the syringe by the plural kinds of cleaning solvents.