A method for applying a heating sequence for a modulator includes, during a first period of time, heating a first heating zone disposed along a length of the modulator without heating a second heating zone to cause a sample trapped from a first transfer line at an entrance of the modulator to move from the first heating zone to the second heating zone. The method also includes, during a second time period, withdrawing the heating of the first heating zone to prevent the sample from entering the modulator from the first transfer line. During a third time period, the method includes heating the second heating zone without heating the first heating zone to reinject the sample into a second transfer line.

A CMV sampling device includes a thermoelectric cooler, a vacuum pump, and one or more holders for one or more capillary microextractor of volatiles (CMV) tubes. The holder thermally contacts the thermoelectric cooler and the vacuum pump is fluidly connected to the CMV tube. The CMV device is useful for sampling of volatile organic compounds from air. The sampling can be carried out rapidly to achieve a sample within the CMV tube that may be placed into a thermal desorption unit (TDU) coupled to an inlet port for introduction of the volatiles into an analytical instrument, such as, a gas chromatograph (GC), an ion mobility spectrometer (IMS), a liquid chromatograph (LC), and/or a mass spectrometer (MS) for analysis of one or more volatiles.

A gas phase component analysis device and a gas phase component analysis method that can prevent degradation of the device due to an unnecessary component and can obtain excellent detection sensitivity are provided.

A gas phase component analysis device (1) includes a heating unit (2) configured to heat a specimen to generate a gas phase component composite, a first column (31) into which the gas phase component composite is introduced, a second column (32) that is a separation column connected with the first column (31) through a connection unit (33), an isothermal oven (3) housing the first column (31), the second column (32), and the connection unit (33), a detection unit (4) configured to detect a gas phase component having passed through the second column (32), and a suction unit (5) connected with the connection unit (33).

A chromatography system includes a modulator, a chromatograph, a cooler, and a detector. The chromatograph is connected to the modulator by a first heated transfer line. The detector is connected to the modulator by a second heated transfer line. The cooler is connected to the modulator. The modulator is arranged outside of the chromatograph.

A chromatography system includes a modulator, a chromatograph, a cooler, and a detector. The chromatograph is connected to the modulator by a first heated transfer line. The detector is connected to the modulator by a second heated transfer line. The cooler is connected to the modulator. The modulator is arranged outside of the chromatograph.

A sample vessel assembly to carry out a sorption analysis in a container provided with a cooling liquid. The sample vessel assembly includes a sample vessel configured to be suspended within the container. The sample vessel has a sample holding region at a sample end of the vessel to hold a sample to be analyzed. A wick is disposed on the sample vessel and surrounds the sample holding region. The wick extends from the sample holding region to project toward a bottom of the container and draw the cooling liquid over the sample holding region when the sample vessel is disposed in an analysis position in the container.

A system and method of determining levels of contaminants in a base gas. A gas chromatography column is used as part of a cold trap. A sample of a base gas is fed through the gas chromatography column. Due to the temperature of the gas chromatography column, some of the contaminants concentrate. A purified carrier gas is directed through the reinforced tube assembly after contaminants have collected. The gas chromatography column is heated to a second temperature that releases at least some of the concentrated contaminants. The contaminants mix with the purified carrier gas to create a contaminated carrier gas. The contaminated carrier gas is directed to one or more testing units that analyze the contaminated carrier gas to quantify the contaminants.

A sample vessel assembly to carry out a sorption analysis in a container provided with a cooling liquid. The sample vessel assembly includes a sample vessel configured to be suspended within the container. The sample vessel has a sample holding region at a sample end of the vessel to hold a sample to be analyzed. A wick is disposed on the sample vessel and surrounds the sample holding region. The wick extends from the sample holding region to project toward a bottom of the container and draw the cooling liquid over the sample holding region when the sample vessel is disposed in an analysis position in the container.

A chromatography system includes a modulator, a chromatograph, a cooler, and a detector. The chromatograph is connected to the modulator by a first heated transfer line. The detector is connected to the modulator by a second heated transfer line. The cooler is connected to the modulator. The modulator is arranged outside of the chromatograph.

A gas phase component analysis device and a gas phase component analysis method that can prevent degradation of the device due to an unnecessary component and can obtain excellent detection sensitivity are provided. A gas phase component analysis device (1) includes a heating unit (2) configured to heat a specimen to generate a gas phase component composite, a first column (31) into which the gas phase component composite is introduced, a second column (32) that is a separation column connected with the first column (31) through a connection unit (33), an isothermal oven (3) housing the first column (31), the second column (32), and the connection unit (33), a detection unit (4) configured to detect a gas phase component having passed through the second column (32), and a suction unit (5) connected with the connection unit (33).