An electrochemical sensor is provided having a housing with an opening therein. The housing defines a chamber. The sensor includes a primary cell having a primary working electrode aligned with the opening in the housing so that the primary working electrode is exposed to an environment outside of the chamber. A primary counter electrode is sealed within the chamber. The sensor includes a secondary cell having a secondary working electrode sealed within the chamber, and a secondary counter electrode sealed within the chamber.

A test device for a detector for detecting gas or a gas/particle mixture, includes a joining means for joining the test device to the detector; a container configured so as to receive a gas or a test gas/particle mixture; a diffusion means associated with the container and designed to diffuse the gas or the test gas/particle mixture in the detector; an energy source; and a radio apparatus able to manage local radio communication in order to remotely trigger the diffusion of the gas or of the test gas/particle mixture in the diffusion means from a control means. A test system comprising at least one test device, at least one radio gateway, a control network comprising a control unit able to remotely control the test device and at least one communication link between the control unit and the radio gateway, said gateway being able to connect the radio apparatus and the control network.

A test device for testing of an oxygen sensor uses a compressor to draw air from an external environment and deliver compressed air into a gas separation unit. A gas separation membrane is located in a passage of the gas separation unit such that compressed air from the compressor travels through the passage and passes through the gas separation membrane. The gas separation membrane separates at least one of nitrogen and oxygen from the compressed air to produce a calibration gas having a calibrated amount of oxygen that is different from an amount of oxygen in the air. The calibration gas coupling is configured to be fluidly connected to the oxygen sensor such that the calibration gas is deliverable from the calibration gas coupling to the oxygen sensor.

A combined automatic dependent surveillance broadcast (ADS-B) and carbon monoxide (CO) detecting device includes an ADS-B circuitry configured to receive an ADS-B transmission, a CO sensor configured to obtain a CO reading for ambient air in an aircraft cabin, a processor configured to generate a data stream combining the ADS-B transmission and the CO reading, and a wireless communication circuitry configured to provide the data stream to at least one aircraft crew computing device.

A gas sensor includes an electrically conductive membrane that bends with an applied surface stress, a fixing member disposed outside the membrane, a coupling portion that couples together the membrane and the fixing member, a flexible resistor whose resistance value changes in accordance with a deflection that occurs in the coupling portion, a conductive support substrate connected to the fixing member and disposed with a gap between the membrane and the coupling portion, a receptor which is formed on an area including the center of a surface on one side of the membrane which is opposite to the other side facing the support substrate, and deforms in accordance with a substance adsorbed, a first terminal capable of applying a first potential to the membrane, a second terminal capable of applying a second potential to the support substrate, and an insulating portion electrically insulating the fixing member from the support substrate.

An analysis condition adjusting device of a fuel analyzer includes a first NOx computing unit for calculating a reference NOx estimation value using a previously obtained first industrial analysis value of a fuel sample, a second NOx computing unit for calculating a plurality of varied NOx estimation value by varying a value of each of components of the first industrial analysis value, a NOx error computing unit for computing an error as a NOx error between the reference NOx estimation value and each of the varied NOx estimation values, an analysis error tolerance range setting unit for setting an analysis error tolerance range of each of the components based on a value variation amount of each of the components, the value variation amount being defined such that the NOx error is within a tolerance range, and an analysis condition adjusting unit for adjusting an analysis condition of a fuel analyzer.

A method determines a potential poisoning of a sensor of an electronic nose by a volatile compound following an exposure of the sensor to a gaseous sample including at least this volatile compound. If there is poisoning, the method determines whether the sensor is still functional such that the sensor is still capable of carrying out one or a plurality of reliable measurements, or on the contrary, whether the sensor is saturated and must no longer be used. The method may be used with any type of electronic nose.

A gas measuring device (100, 400). The gas measuring device (100, 400) includes a chemical gas sensor (103, 417) and a testing unit (101). The testing unit (101) includes a base, a gas duct arrangement arranged at the base with a first gas duct (111, 401) and with at least one additional gas duct (113, 405) and at least one electrochemical gas generator (105, 403, 407). The at least one gas generator (105, 403, 407) is configured to send at least one test gas into the first gas duct (111, 401) in a first state and into the at least one additional gas duct (113, 405) in an additional state. The first gas duct (111, 401) and the at least one additional gas duct (113, 405) are each configured to send at least one gas to the gas sensor (103, 417). The first gas duct (111, 401) differs from the at least one additional gas duct (113, 405).

A diagnostic system (10) is provided and includes a sensor (24) disposed downstream from an exhaust gas aftertreatment system. Also included in the diagnostic system (10) is a central diagnostic unit (35) configured to diagnose a condensation condition associated with the sensor (24) for mitigating a sensor failure due to water condensation on the sensor (24), the central diagnostic unit (35) performing the diagnosis on the condensation condition based on water storage and release information related to a component of the exhaust gas aftertreatment system. The sensor (24) is activated based on the water storage and release information.

The method for calculating concentration ratio includes: (a) heating a gas sensor element to a temperature at which both of two gas components introduced in a gas sensor element react, and maintaining the temperature for a predetermined period to measure an electrical resistance value of the gas sensor element; (b) heating the gas sensor element to a temperature at which only any of the two gas components reacts, and maintaining the temperature for a predetermined period to measure an electrical resistance value of the gas sensor element; and (c) calculating a concentration ratio of the two gas components based on a combination of the electrical resistance value in (a) and the electrical resistance value in (b).