A continuous gas detection and monitoring apparatus includes a gas detection and monitoring unit mounted in a sealable case, and a gas sensor in sealed fluid communication with an ambient atmosphere outside the case, a temperature and humidity sensor in sealed fluid communication with the inner volume of the case, a pressure sensor, data storage, and a gas sensor operatively connected to a data processor, and an externally operable switch for selectively connecting the data processor to the data storage to allow data transfer from the data storage to the data processor. A plumbing system includes a pump system, a solenoid system, and tubes interconnecting the gas sensor, pumping system, solenoid system, and ambient external environment. The gas sensor is mounted to the gas sensor housing and is in sealed fluid communication with the external environment via the plumbing system.

An air quality monitoring device and associate method of monitoring air quality is provided. An example air quality monitoring device may include a housing comprising a chamber and an inlet port, a plurality of sensors to measure air quality data, and a controller. The inlet port is structured to selectively receive ambient air flow such that the sensors measure air quality data associated with the ambient air flow and to selectively receive air flow directly from an outlet port of a positive airway pressure machine such that the sensors measure air quality data associated with the air flow from positive airway pressure machine. The controller compares the measured air quality data associated with the ambient air flow with the measured air quality data associated with the air flow from the positive airway pressure machine to determine net air quality data associated with air flow from the positive airway pressure machine.

A method and an analyzer for detecting impurities in refrigerant (e.g. methyl chloride (R40) or Chlorodifiuoromethane (R22)), wherein the refrigerant analyzer (12) includes a first sensing device (16), preferably a non-dispersive infrared sensor (NDIR), in flow communication with a second sensing device (18), preferably an electrochemical sensor. The first sensing device is configured to determine a first characteristic of a refrigerant (e.g. absorbance in the IR range), and the second sensing device is configured to detect a second characteristic of the refrigerant (e.g. concentration in ppmv). Preferably, the refrigerant analyzer is a part of a system for detecting impurities (10) and further preferably it comprises flow regulators (20), a scrubber (24) and a processor (22). The scrubber is preferably in flow communication with the first sensing device and it preferably comprises a packing material comprising alumina (Al2O3, aluminum oxide).

A long term portable gas detecting and monitoring apparatus includes a case having a continuous sidewall including a first end closed by a first end cap, and a second end closed by a second end cap connected sealably and removably to the continuous sidewall. The continuous sidewall is triangular between the closed end and the open having three sides and three corners, two of the three sides being straight and equal in length, one of the three sides being rounded, and each of the three corners being rounded. A long term gas detection and monitoring unit mounted in the case includes gas, and temperature and humidity sensors in communication with an ambient atmosphere outside the case, a data processor operatively connected to the sensors, data storage, an information display viewable through the case, and a calibration unit for calibrating the gas sensor to a predetermined gas concentration measured by the 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.

Infrared gas detection system comprising a gas inlet, an infrared gas analyzer connected to the gas inlet and a secondary gas sensor connected to the gas inlet, and an evaluation device evaluating the measurement signals from both the infrared gas analyzer and from the secondary gas sensor, such that a gas is identified only if both the infrared measurement signal and the secondary measurement signal coincide in time.

The present invention relates to methods and processes for detecting a substance. In preferred embodiments the method comprises: displaying a three-dimensional graph on a screen where each axis of the three-dimensional graph represents a parameter for detecting a substance; defining a rectangular volume in the three-dimensional graph wherein limits of the rectangular volume define when a substance has been detected; displaying the rectangular volume in the three-dimensional graph; analyzing a substance and displaying a point on the three-dimensional graph that represents the detected substance in terms of the parameters represented by the axes of the three-dimensional graph; and determining whether the point is within the rectangular volume.

The invention concerns an on-board device and a mobile method for capturing and recording the fine particles and/or the density of NOx gases in the air for the purpose of dynamically using the gathered data. The device (1) comprises at least one sensor (3) for sensing particles and/or the density of the NOx gases in the air, capable of counting a number of particles or dust particles present in the air, having a dimension ranging between defined values in a volume of air, and a means (7,19) for displaying and/or recording said number and/or density correlated to a determined measurement location of the sensor, the device further being configured to be installed on and to function on a moving vehicle (2) and to be initialised at certain points on the map, or indeed recalibrated, in regular reference to fixed standardised sensors.

The invention relates to a method for the identification of an analyte in a sample fluid. The method comprises the performance of a set of measurements on at least two sensors of different types. Sensors of different types may comprise Gas Chromatography sensors, CMOS gas sensors, a combination thereof, or more generally sensors in which it is possible to control a first physical parameter and measure, for different values of the first parameter, a second physical parameter representative of at least a concentration of the analyte. The method comprises the detection of maxima of the second parameter, the access to databases in order to find reference values of the first parameters in which maxima are found, and the comparison of values at which maxima are found and reference values, on the two sensors.

An analyzing device is provided, which can accurately analyze information related to generation sources. A generation source analyzing device is provided, which includes a measurement value acquiring unit to acquire time-series measurement values of a concentration of each of a plurality of measured object components at a measurement point, a correlation calculating unit to calculate a correlation value between the time-series measurement values of at least one set of the measured object components, and a generation source analyzing unit to analyze information related to generation sources of at least one measured object component based on the correlation value calculated by the correlation calculating unit.