A gas sampling lance with a gas sample pipe for sampling gases wherein the gas sample pipe is divided in a lance pipe and a connecting pipe which connects the lance pipe to a gas scrubber, a first scraper to clean the inside of the lance pipe and a second scraper to clean the inside of the connecting pipe.

A sensor system (100) or a sensing method minimizes the loss of aroma chemicals or other analytes in a sample gas while controlling the temperature and humidity of the sample gas. The system (100) may employ a humidifier (120) that adds water vapor to sample gas to provide a known water content, e.g., a saturated humidity at a known temperature. A sensing unit (130) may accurately measure the composition of the sample gas having a known water content, e.g., at a higher known temperature.

A combustion analyzer system includes an analyzer unit, a primary analysis probe and one or more remote probes. The analyzer unit includes a condensation removal unit and two or more electrochemical sensors to detect at least oxygen and carbon monoxide. The analyzer unit or the primary analysis probe include a means for condensing and eliminating liquid in the combustion gas to be analyzed.

An automatic pathogen-from-expiration detection system and method is disclosed. The system comprises a gas pathogen recovery unit, a pathogen concentration unit and a sample detection unit. The method comprises: making the sample recovered by the gas pathogen recovery unit enter the pathogen concentration unit; in the pathogen concentration unit, gradually biasing the pathogen particles in the sample to the positive electrode side into the concentration channel under the action of the electrode; applying a fluctuating voltage greater than zero to a single sub-positive electrode, and alternating the voltage of the sub-positive electrode adjacent thereto with the fluctuating voltage, so that a varying potential difference is formed between the adjacent sub-positive electrodes, wherein the pathogen particles are gradually enriched in the middle region of the two adjacent sub-positive electrodes, and the concentrated sample is driven to move to the sample detection unit; and immediately detecting the concentrated sample in the sample detection unit. The detection of the present invention is highly sensitive, low cost and enables the continuous and rapid integrated sampling and detection of pathogens for multiple individuals.

An air sampling system is disclosed. The air sampling system includes: an air intake unit defining an inlet and an air inflow channel; a fan configured to cause air in a sampling environment to flow into the air inflow channel via the inlet; a cooling unit for cooling air in the air inflow channel; a collection chamber for collecting liquid water condensed from air in the air inflow channel, the collection chamber being removably coupled to the air intake unit and including an active target substrate having a surface that is coated with bioreceptors; and an optical detection unit including a light source, the optical detection unit being configured to illuminate the active target substrate with the light source.

A sensor system (100) or a sensing method minimizes the loss of aroma chemicals or other analytes in a sample gas while controlling the temperature and humidity of the sample gas. The system (100) may employ a humidifier (120) that adds water vapor to sample gas to provide a known water content, e.g., a saturated humidity at a known temperature. A sensing unit (130) may accurately measure the composition of the sample gas having a known water content, e.g., at a higher known temperature.

A system for real-time detection of airborne pathogens is disclosed. The system includes: an air intake unit defining an inlet and an air inflow channel; a fan configured to cause air in a sampling environment to flow into the air inflow channel via the inlet; a cooling unit for cooling air in the air inflow channel; a collection chamber for collecting liquid water condensed from air in the air inflow channel, the collection chamber including: an active target substrate having a surface that is coated with bioreceptors; and a reference target substrate that is not coated with bioreceptors, and an optical detection unit that is configured to independently illuminate the active target substrate and the reference target substrate with light for detecting presence of an airborne pathogen.

In an example, a thermal extraction apparatus includes: a housing having a gas inlet and a gas outlet to receive a gas flow through the housing from the gas inlet to the gas outlet, and a side opening to receive a sample collector, having a sample collector adsorbent containing a vapor sample, into a sample collector location; a pump to generate the gas flow; a heater to heat the sample collector adsorbent of the sample collector to a temperature sufficient to release the vapor sample; a thermal desorption (TD) tube connected with the gas outlet of the housing to receive the gas flow downstream of the sample collector and collect the vapor sample released from the sample collector adsorbent of the sample collector; and a cooling member in heat exchange with the TD tube to cool the TD tube.

Portable dynamic vapor micro-extraction systems for use in real-time trace vapor collection in the field. The system includes one or more wafer collection modules or cartridges that include a plurality of sample collection capillaries, each cartridge being receivable into an associated vapor collection device of the system, for collecting a vapor sample in the field. The vapor collection device includes a thermoelectric cooler providing a cold plate directly thermally coupled to an installed cartridge. The thermoelectric cooler provides cooling to a temperature below ambient temperature, while vapor sampling occurs. A pump draws the vapor sample through a sample port of the device, and into the received cartridge, such that target molecules to be detected are adsorbed. The system can further include a cartridge storage compartment, for storing the cartridges.

A thermal desorption tube collection system uses a thermoelectric cooler to collect and concentrate gas samples. In some modes, the operation of the cooler is reversed to flow the concentrated sample directly into a separator such as a gas chromatography system. Components resolved in time by a thermal desorption separator accumulate in a sample cell and are analyzed by electromagnetic radiation-based spectroscopic techniques. Also presented are methods for analyzing biogas samples.