The present application relates to a device for extracting volatile components from a sample received in a sample vessel, wherein the sample vessel is closed in a gas-tight manner. The device moreover has a discharge line and a supply line, which protrude into the sample vessel. The supply line comprises a first valve with which a flow of gas through the supply line can be throttled and/or interrupted. A suction opening of a pump is fluidically connected to the discharge line via a first fluid line, such that the pressure conditions in the device can be controlled by the capacity of the pump and by the setting of the first valve. A second fluid line fluidically connects the supply line to an output opening of the pump, such that sample vessel, supply line, discharge line and pump form a closed gas circuit. A trap element with at least one sorption material is fluidically connected to the first fluid line or the second fluid line.

The invention relates to a device for determining a volume of gas in a sample contained in a vessel, the device comprising: a frame configured to attach the vessel; a needle having a longitudinal axis, comprising a proximal part and a distal part, the distal part being configured to pierce the vessel and the proximal part comprising a lumen; and an analysis compartment comprising a cell in fluid communication with the lumen of the proximal part of the needle. The invention also relates to a method for determining a volume of gas in a sample contained in a vessel.

System, method, and apparatus embodiments characterize potential air emissions during the pig receiver depressurization. The mass flow rate, pressure, and temperature of exhaust gas released from the pig receiver are ascertained using a mass flow meter, pressure gauge, and temperature gauge, respectively. A flow meter and control valve regulate flow of exhaust gas through a sampling line and into a grab sample collection train. The grab sample collection train includes grab sample containers (e.g., piston cylinders, double-ended cylinders, and evacuated canisters) that collect exhaust gas samples over a range of pressures. The exhaust gas samples are used to determine the concentrations of gas components in the exhaust gas over the range of pressures. These concentrations are interpolated and/or extrapolated to provide a concentration versus pressure curve for each identified component in the exhaust gas. The ascertained mass flow rate and gas concentration curve are used to characterize potential mass emissions of each gas component during pig receiver depressurization.

An autosampler is provided with a needle that has a capacity to retain a sample therein and has both ends each formed in a pointed shape, a first adapter that has an opening and causes the needle and a syringe pump to be in communication with each other through the insertion of the upper end part of the needle into the opening, and a second adapter that connects the needle and a mobile-phase liquid-delivery flow path using a structure similar to that of the first adapter. The autosampler is configured such that the first adapter and the second adapter are attached to and removed from the upper end part of the needle so as to create flow paths including the needle as necessary and carry out a sampling operation and injecting operation.

There is provided a nitrogen analyzing method for quantitative analysis of nitrogen in a specimen by a chemiluminescence method using ozone which is capable of measuring a concentration of nitrogen contained in the specimen with still higher accuracy, as well as a nitrogen analyzer used for practicing the analyzing method. Also, according to the present invention, there is provided a nitrogen analyzing method and a nitrogen analyzer which have a less adverse influence on human body and are also capable of further reducing environmental burden even when analyzing nitrogen in fuel-related specimens. The nitrogen analyzing method according to the present invention comprises the steps of burning a specimen comprising a nitrogen compound to generate a specimen gas, allowing the resulting specimen gas to react with ozone to measure a chemiluminescence intensity thereof, and quantitatively determining a concentration of nitrogen in the specimen based on a previously prepared calibration curve expressing a relationship between the chemiluminescence intensity and a weight of nitrogen, wherein the calibration curve is previously prepared from a standard specimen having a nitrogen concentration of 5 to 100 ppm, and the specimen is used in the form of a diluted specimen prepared by diluting the specimen with a solvent into a nitrogen concentration of 5 to 100 ppm.

An apparatus for taking a sample from at least one fluid system and for passing the sample to an analytical evaluation system connects the piston rod of the sample-taking piston with a controllable drive. A flushing gas feed opens into a feed line downstream from a three-way valve, via a shut-off valve. The three-way valve, the controllable drive, and the shut-off valve are coupled with one another so that for taking a sample, the three-way valve releases the path of the sampling line to the sample-taking cylinder, the shut-off valve is open, and the controllable drive withdraws the sample-taking piston from the sample-taking cylinder, and, for applying the sample to the evaluation system, the shut-off valve is closed, the three-way valve is switched to release the path from the sample-taking piston to the feed line, and the controllable drive pushes the sample-taking piston completely back into the sample-taking cylinder.

A sampling device for assisting with an air sampling process that includes a base forming a channel configured for fitting a syringe. The syringe includes a plunger within a barrel and a hub configured to extend out from the base to access a sorbent tube. A lever is provided that is configured to initiate movement of the plunger. A clamp is connected to the lever and positioned within the channel. The clamp is configured to secure a flange and pull the plunger back when the lever is moved back. A guide bridge extends from a front end of the base and forms an opening for the syringe within the channel and limits undesired movement and/or displacement during use. A restrictor is configured to connect to the sorbent tube and defines an orifice to limit the volume and flow rate of sample being pulled into the sorbent tube.

The invention relates to an apparatus for analyzing reactions, comprising at least one reactor (1) and at least two sample vessels (13), wherein, in the case of an apparatus having one reactor (1), the reactor (1) is connected to at least two sample vessels (13), and, in the case of an apparatus having more than one reactor (1), each reactor (1) is connected to at least one sample vessel (13). The invention further relates to a method of analyzing reactions in such an apparatus.

Apparatus, systems, and methods for absorbing gas and measuring gas fluxes are disclosed. This disclosure relates to an apparatus for absorbing a gas, the apparatus comprising a cartridge, the cartridge comprising a housing having a top end opposite a bottom end, a first gas absorbing material disposed within the housing, a second gas absorbing material disposed within the housing, a gas porous separation layer disposed between the first gas absorbing material and the second gas absorbing material, and a top end cap, wherein the top end is capable of forming a gas-tight coupling with the top end cap. A tube may be coupled to the cartridge to transfer a gas sample from a syringe to the cartridge by a syringe pump, where the gas sample is absorbed by a gas absorbing material. The cartridge may be in gaseous communication with a chamber to receive the gas sample.