Disclosed herein are devices comprising: a sample conduit providing a path for fluid flow extending from a sample inlet to a sample outlet; a thermal housing enclosing the sample conduit, wherein the thermal housing comprises a plurality of measurement regions; and a motorized stage translatable along the thermal housing from a first location to a second location so as to align a detector with one or more of the plurality of measurement regions. Also disclosed are methods of use of the devices described herein.

Disclosed herein are devices comprising: a sample conduit providing a path for fluid flow extending from a sample inlet to a sample outlet; a thermal housing enclosing the sample conduit, wherein the thermal housing comprises a plurality of measurement regions; and a motorized stage translatable along the thermal housing from a first location to a second location so as to align a detector with one or more of the plurality of measurement regions. Also disclosed are methods of use of the devices described herein.

A thermoresistive gas sensor includes two identical, flat meshes that consist of a semiconductor material with a predetermined type of conductivity and that are interconnected in sections of an electric measuring bridge that are diametrically opposite one another, wherein each mesh of the two identical, flat meshes has mesh webs that extend parallel, adjacent to one another and that are connected electrically in parallel at the ends, where the mesh webs of the two meshes extend alternately adjacent to one another in a shared mesh plane horizontally across a window opening in a carrier plate.

A thermoresistive gas sensor includes two identical, flat meshes that consist of a semiconductor material with a predetermined type of conductivity and that are interconnected in sections of an electric measuring bridge that are diametrically opposite one another, wherein each mesh of the two identical, flat meshes has mesh webs that extend parallel, adjacent to one another and that are connected electrically in parallel at the ends, where the mesh webs of the two meshes extend alternately adjacent to one another in a shared mesh plane horizontally across a window opening in a carrier plate.

The invention relates to a heat flux sensor including:

a heating wire (1) including a material capable of being taken to a determined temperature by Joule effect, suited to being connected to an electrical source,

a resonator (2) of nano electro mechanical system (NEMS) type including: a beam (20) suspended with respect to a support (21), an actuating device (22) capable of generating a vibration of said beam under the effect of an excitation signal, a detection device configured to measure a displacement of said beam in the course of said vibration and to emit an output signal having a resonance at the resonance frequency of the resonator, said resonance frequency depending on the temperature of the beam,
wherein one end (20a) of the beam (20) is integral with the heating wire (1) so as to enable a conduction of heat from the heating wire to the beam, a variation in temperature of the heating wire induced by a variation in a characteristic of a fluid surrounding said wire causing a variation in the resonance frequency of the resonator.

The invention relates to a heat flux sensor including:

a heating wire (1) including a material capable of being taken to a determined temperature by Joule effect, suited to being connected to an electrical source,

a resonator (2) of nano electro mechanical system (NEMS) type including: a beam (20) suspended with respect to a support (21), an actuating device (22) capable of generating a vibration of said beam under the effect of an excitation signal, a detection device configured to measure a displacement of said beam in the course of said vibration and to emit an output signal having a resonance at the resonance frequency of the resonator, said resonance frequency depending on the temperature of the beam,
wherein one end (20a) of the beam (20) is integral with the heating wire (1) so as to enable a conduction of heat from the heating wire to the beam, a variation in temperature of the heating wire induced by a variation in a characteristic of a fluid surrounding said wire causing a variation in the resonance frequency of the resonator.

Embodiments of a gas detector with a first gas sensor having a first gas specificity and a first response time and a second gas sensor having a second gas specificity and a second response time. The first gas specificity is different than the second gas specificity, the first response time is different than the second response time, or both the first gas specificity and the first response time are different than the second gas specificity and the second response time. A readout and analysis circuit is coupled to the first and second gas sensors to read and analyze data from the first and second gas sensors, and a control circuit is coupled to the readout and analysis circuit and to the first and second gas sensors to execute logic that operates the first gas sensor, the second gas sensor, or both the first and second gas sensors.

Embodiments of a gas detector with a first gas sensor having a first gas specificity and a first response time and a second gas sensor having a second gas specificity and a second response time. The first gas specificity is different than the second gas specificity, the first response time is different than the second response time, or both the first gas specificity and the first response time are different than the second gas specificity and the second response time. A readout and analysis circuit is coupled to the first and second gas sensors to read and analyze data from the first and second gas sensors, and a control circuit is coupled to the readout and analysis circuit and to the first and second gas sensors to execute logic that operates the first gas sensor, the second gas sensor, or both the first and second gas sensors.

A thermal conductivity detector includes a first pipe passage and an exhaust pipe passage. The first pipe passage is accommodated in a cell block together with a heating device. The exhaust pipe passage has an outlet port at the downstream end, and most of the exhaust pipe passage including the downstream end is drawn out of the cell block. The heating device maintains the space in the cell block at a temperature capable of vaporizing the sample. A filament is accommodated in the first pipe passage. The gas passing through the first pipe passage is discharged out of the thermal conductivity detector through the exhaust pipe passage outlet port. On the inner surface of the exhaust pipe passage, a coating having resistance to a cleaning fluid for removing the adhered substance due to the sample gas is formed.

A thermal conductivity detector includes a first pipe passage and an exhaust pipe passage. The first pipe passage is accommodated in a cell block together with a heating device. The exhaust pipe passage has an outlet port at the downstream end, and most of the exhaust pipe passage including the downstream end is drawn out of the cell block. The heating device maintains the space in the cell block at a temperature capable of vaporizing the sample. A filament is accommodated in the first pipe passage. The gas passing through the first pipe passage is discharged out of the thermal conductivity detector through the exhaust pipe passage outlet port. On the inner surface of the exhaust pipe passage, a coating having resistance to a cleaning fluid for removing the adhered substance due to the sample gas is formed.