Systems and methods for gas detection within vehicles are disclosed herein. An example method includes monitoring background gas concentrations in a vehicle using a robot having a gas module having a non-selective sensor and a selective sensor, determining a concern index based on output of the gas module, determining when the concern index exceeds a threshold which indicates presence of a non-atmospheric gas, causing the robot to traverse an operating area when the concern index exceeds the threshold to search for a source of the non-atmospheric gas by measuring gas concentration gradients, classifying the non-atmospheric gas using the selective sensor of the gas module and identifying a location of the source of the non-atmospheric gas in the vehicle based on the gas concentration gradients.

Systems, methods and apparatus for the thermal conversion of biomass into biochar. A mobile platform may be used to maneuver a mobile biochar generation system within a field of biomass. The biomass may be harvested, preprocessed and pyrolyzed. After pyrolyzation, the biochar may be cooled to a predetermined temperature by integrating water and liquid nutrients into the biochar. The system may then control the application of the infused biochar by adjusting a spreading attachment and a plowing attachment.

A substance sensor includes sensitive membranes to react with substances included in the odors of a gas in correspondence with the substances, and is configured to detect the reaction values of the sensitive membranes. An odor specifier specifies the odors of the gas on the basis of the reaction values of the sensitive membranes. A reaction value calculator calculates reaction values corresponding to the odors specified by the odor specifier on the basis of the reaction values of the sensitive membranes. A percentage calculator calculates the percentages of the reaction values corresponding to the odors specified by the odor specifier to the total of the reaction values corresponding to the odors. A display displays the percentages of the reaction values corresponding to the odors, calculated by the percentage calculator, so that comparison of the percentages is enabled between the odors specified by the odor specifier.

A MEMS gas sensor (A), array thereof, and preparation method therefor. The MEMS gas sensor comprises a first substrate (A2) provided with a first cavity (A1), and N gas detection assemblies (A3) provided at an opening of A1, each A3 comprises: a supporting arm (A31) and a gas detection part (A32) provided on the A31; the A32 comprises a strip-shaped heating electrode part (A321), an insulating layer (A322), a strip-shaped detection electrode part (A323), and a gas-sensitive material part (A324) that are stacked sequentially; the A323 comprises a first detection electrode part (A323-1) and a second detection electrode part (A323-2) with a first opening (A325) therebetween; the A324 is provided at the A325; a first end of the A324 is connected to the A323-1, a second end of the A324 is connected to the A323-2; strip-shaped heating electrode parts in each A3 are connected sequentially to form a heater (A8).

A portable device for measuring gas in a closed space includes an air intake and exhaust unit configured to suction external air and discharge the suctioned air, a sensor unit configured to measure characteristics of the air suctioned by the air intake and exhaust unit, a communication unit configured to communicate with a host system, a power supply unit configured to supply power to the air intake and exhaust unit, the sensor unit, and the communication unit, and a control unit configured to control the air intake and exhaust unit, the sensor unit, the communication unit, and the power supply unit so that the sensor unit measures the characteristics of the air suctioned by the air intake and exhaust unit and configured to transmit measurement information to the host system through the communication unit.

An odor measurement apparatus includes an odor sensor detecting an odor and an imaging device having a lens portion, in which an imaging direction of the imaging device and an introduction direction of air when the air is guided to a sensor surface of the odor sensor through an introduction port are substantially the same direction. The odor measurement apparatus detects odor substances contained in air using a sensor when an odor is measured, and measures attribute information of a measurement target or the like of the odor. An odor data management apparatus stores and manages odor data measured by the odor measurement apparatus.

A battery retaining system for a portable oxygen concentrator includes a first rail configured to receive a first slide of a battery, a second rail configured to receive a second slide of the battery, the second rail being spaced apart from the first rail so as to form a channel configured to receive the battery, and a flexible stiffening mechanism configured to impart a biasing force on a surface of the battery when the battery is received within the channel. The flexible stiffening mechanism includes a protrusion projecting from the first rail at least partially towards the second rail and a slit positioned behind the protrusion and configured to facilitate travel of the protrusion fore and aft.

A system includes a plurality of semiconductor processing tools; a carrier purge station; a carrier repair station; and an overhead transport (OHT) loop for transporting one or more substrate carriers among the plurality of semiconductor processing tools, the carrier purge station, and the carrier repair station. The carrier purge station is configured to receive a substrate carrier from one of the plurality of semiconductor processing tools, purge the substrate carrier with an inert gas, and determine if the substrate carrier needs repair. The carrier repair station is configured to receive a substrate carrier to be repaired and replace one or more parts in the substrate carrier.

An improved air quality monitoring device provides accurate and reliable predictions regarding likelihood for microbial growth on building walls. The present invention comprises a housing adapted to affix the device to a building wall, a first sensor array placed in close proximity to the wall, a second sensor array and a processing means operatively connected to the first sensor array and the second sensor array. The first sensor array provides inputs such as relative humidity at the surface of the wall, the wall temperature and wall pressure. The second sensor array provides inputs such as relative humidity, temperature pressure and quality of ambient air. Using inputs from the first sensor array and the second sensor array, the processing means generates an output representative of the likelihood of microbial growth and the likelihood that the wall moisture is caused by condensation. A system of networked monitoring devices is also described.

A gas sensor includes a suction inlet, a housing communicating with the suction inlet, a gas sensor array disposed in an inside of the housing, and a suction unit disposed at an end of the housing. The suction unit is configured to perform a first suction conveying a gas component in air to the gas sensor array through the suction inlet, and perform a second suction conveying the gas component to the gas sensor array at a flow rate smaller than a flow rate of the first suction. The suction unit is configured to perform the second suction together with the first suction. The gas sensor array is configured to operate while the suction unit performs the second suction.