A remote test apparatus is configured to simulate an environment of at least one remotely located room and configured to receive at least one air sample from the at least one remotely located room. The apparatus includes a sealed enclosure forming an interior cavity and including an inlet in connection with the at least one remotely located room and an outlet in connection with a sample collection unit. The sample collection unit is configured to communicate the at least one air sample from the remotely located room at a first flow rate. The apparatus further includes at least one sensor disposed in the interior cavity and at least one air transfer unit configured to transfer test air from the interior cavity of the sealed enclosure to the at least one sensor at a second flow rate.

An in-vehicle exhaust gas analysis system, which is provided with a flowmeter, and an exhaust gas analyzer to analyze a concentration of a measurement target component contained in exhaust gas, includes a standard gas supply mechanism to supply a standard gas containing a predetermined component to the flowmeter and the exhaust gas analyzer. The system is configured to include a detected mass calculation section to calculate a detected mass of a predetermined component by using a flow rate obtained by the flowmeter and a concentration of the predetermined component obtained by the exhaust gas analyzer, a supply mass acquisition section to acquire a supply mass of the predetermined component supplied from the standard gas supply mechanism to the flowmeter and the exhaust gas analyzer, and a mass comparison section to compare a detected mass calculated by the mass calculation section and a supply mass acquired by the supply mass acquisition section.

A process (100) for adjusting a gas supply system (300, 400) includes a calibration step for calibrating (101) a gas sensor (303, 401) at a first calibration time (t1) with a defined concentration of test gas. A first calibration result (S1) is determined during the calibration. At least one gas supply measured value (M1) is determined at a time (t2) preceding the first calibration time (t1). A determination step determines (103) a gas supply reference value (G1) by the at least one gas supply measured value (M1) being put into a mathematical relationship with the first calibration result (S1) and with a calibration result (S0) of the gas sensor (303, 401), which was determined at a time preceding the first calibration time (t1). An adjustment step adjusts (105) the gas supply system on the basis of the gas supply reference value (G1).

A system and method for testing a gas sensor with a test gas and that recovers the test gas after testing. The test gas is stored in a test gas source, and delivered to the gas sensor through a supply circuit. After the test is completed, gas is withdrawn from the supply circuit into a recycle circuit. A compressor in the recycle circuit pulls the test gas into the recycle circuit, pressurizes the test gas and discharges the pressurized test gas back into the test gas source. Valves are in the supply and recycle circuits, which when selectively opened and closed changes between testing and recycle configurations. The recycle flow is filtered to prevent air and other non-test gas substances from being introduced into the test gas source.

Provided is a gas sensor and methods of monitoring the same. The gas sensor may detect gas restrictions within the gas sensor. The gas sensor may include a test gas diffusion path allowing for monitoring of restrictions within the gas sensor. A pulse of test gas may be electrochemically generated into a void disposed between the membrane and capillary of the gas sensor. The resulting transient signal on the sensing electrode may be analyzed to determine the degree of restriction present in the gas sensor.

An apparatus for evaluating a response time of gas sensors includes: a pipe; a first gas supplier for supplying a first gas to the pipe; a second gas adding machine for adding a second gas to the first gas in the pipe; and gas sensors for detecting components in a mixed gas of the first gas and the second gas, each of the gas sensors being attached to the pipe on a downstream side of an addition position of the second gas in a flow direction of the first gas. The second gas adding machine includes: a supply source of the second gas; a connecting pipe for connecting the supply source to the pipe; and a connecting pipe on-off valve for opening and closing the connecting pipe.

Methods, systems, and apparatus for configuring a multi-modal gas sensor array that includes multiple gas sensors. The multiple gas sensors include a first type of gas sensor and a second, different type of gas sensor. A test gas is provided to the gas sensors, where the test gas includes known analytes. Data generated by each of the gas sensors in response to the known analytes in the test gas is collected. A proper subset of gas sensors is selected to include in an optimized gas sensor array, based on the responses of the gas sensors to the known analytes in the test gas meeting a threshold response and meeting a threshold temporal response. The multi-modal gas sensor array is configured using the proper subset of gas sensors.

Gas sensors for the detection of rare events consume very little or no power. The sensors include materials that interact with a target gas. Accumulation of the target gas on the sensor materials leads to a change in electrical properties of the sensor. The sensors may have high gain, meaning that a large electrical change is induced upon gas accumulation. The sensor might change from an extremely high resistance (open circuit) to a measurably low resistance, or it might change from a relatively low capacitance to a high capacitance. The gas sensors are connected to electronics that can transmit an alarm signal after gas has been detected. The electronics may be in a low power sleep mode until awakened by a signal from the sensor.

A method for testing a gas sensor and a gas sensor are disclosed. In an embodiment a method for testing at least one gas sensor includes exposing in a first measurement the gas sensor to a test gas under first gas conditions including a first pressure and exposing in a second measurement the gas sensor to the test gas under second gas conditions including a second pressure, the second gas conditions being different from the first gas conditions, wherein the second pressure is different from the first pressure, and/or wherein the gas sensor is exposed to an intermediate pressure different from the first pressure between the first measurement and the second measurement.

A system and a method for accurately testing gas leak detectors by considering multiple operational parameters as per the standard requirements are disclosed. The system comprises one or more gas cylinders, a test execution chamber, mass flow controllers (MFCs), and a control system. The test execution chamber is connected to the gas cylinders via test gas pipelines and a plurality of valves, and the mass flow controllers. The test execution chamber further comprises a first chamber and a second chamber, which are connected to form a closed cycle, thereby saving consumption of the testing gases. The control system in communication with the mechanized system, thereby controlling the operation of the system for accurately testing the gas leak detector test samples. The performance of the one or more gas leak detector test samples is controlled by adjusting the density of the testing gas to a predetermined value and as per the standard requirements.