Abstract: Embodiments relate generally to a gas detector test fixture that recycles test gas. A portable gas detector test fixture, comprises a test chamber, a processor, a docking connector communicatively coupled to the processor, an output device communicatively coupled to the processor, a memory communicatively coupled to the processor, and an application stored in the memory that, when executed by the processor, is configured to conduct a bump test on a portable gas detector plugged into the docking connector and to output the bump test result to the output device. The test fixture further comprises an inflow line configured to connect to a test gas supply line of a test gas container, where the inflow line is coupled to the test chamber, and an outflow line configured to connect to a test gas return line of the test gas container, where the outflow line is coupled to the test chamber.

Abstract: Embodiments relate generally to a gas detector test fixture that recycles test gas. A portable gas detector test fixture, comprises a test chamber, a processor, a docking connector communicatively coupled to the processor, an output device communicatively coupled to the processor, a memory communicatively coupled to the processor, and an application stored in the memory that, when executed by the processor, is configured to conduct a bump test on a portable gas detector plugged into the docking connector and to output the bump test result to the output device. The test fixture further comprises an inflow line configured to connect to a test gas supply line of a test gas container, where the inflow line is coupled to the test chamber, and an outflow line configured to connect to a test gas return line of the test gas container, where the outflow line is coupled to the test chamber.

Abstract: Embodiments relate generally to a gas detector test fixture (102) that recycles test gas, which can then be reused. A portable gas detector test fixture (102), comprises a test chamber (104), a processor (134), a docking connector (132) communicatively coupled to the processor (134), an output device (138) communicatively coupled to the processor (134), a memory (136) communicatively coupled to the processor (134), and an application (137) stored in the memory (136) that, when executed by the processor (134), is configured to conduct a bump test on a portable gas detector (106) plugged into the docking connector (132) and to output the bump test result to the output device (138).

Abstract: Embodiments relate generally to a gas detector test fixture (102) that recycles test gas, which can then be reused. A portable gas detector test fixture (102), comprises a test chamber (104), a processor (134), a docking connector (132) communicatively coupled to the processor (134), an output device (138) communicatively coupled to the processor (134), a memory (136) communicatively coupled to the processor (134), and an application (137) stored in the memory (136) that, when executed by the processor (134), is configured to conduct a bump test on a portable gas detector (106) plugged into the docking connector (132) and to output the bump test result to the output device (138).

Abstract: Embodiments relate generally to gas detector connectivity devices, for example a dongle, to allow for continuous communication of real-time data between a gas detector and a central station. Dongle embodiments typically comprise an IR transceiver, a processor, a wireless interface device, a power source, and a means of attachment. Such dongle embodiments, and their related methods of operation, may allow for retrofitting of legacy gas detectors to provide wireless capabilities.

Abstract: Embodiments relate generally to a gas detector test fixture (102) that recycles test gas, which can then be reused. A portable gas detector test fixture (102), comprises a test chamber (104), a processor (134), a docking connector (132) communicatively coupled to the processor (134), an output device (138) communicatively coupled to the processor (134), a memory (136) communicatively coupled to the processor (134), and an application (137) stored in the memory (136) that, when executed by the processor (134), is configured to conduct a bump test on a portable gas detector (106) plugged into the docking connector (132) and to output the bump test result to the output device (138).

Abstract: Embodiments relate generally to systems and methods for normalizing the pressure proximate to a gas sensor within a gas detector. A rectifier assembly for use with a gas detector may comprise a flow barrier; a first valve connected to the flow barrier configured to open to normalize the pressure proximate to the gas sensor; a second valve connected to the flow barrier configured to open to allow airflow from the pump toward the gas sensor; and one or more retainer rings configured to position the first valve, second valve, and flow barrier with respect to one another, and configured to position the rectifier assembly within a cavity of the gas detector, wherein the rectifier assembly is configured to be located between a pump and at least one gas sensor of the gas detector; and wherein the rectifier assembly is configured to normalize pressure proximate to the gas sensor.

Abstract: Embodiments relate generally to gas detector connectivity devices, for example a dongle, to allow for continuous communication of real-time data between a gas detector and a central station. Dongle embodiments typically comprise an IR transceiver, a processor, a wireless interface device, a power source, and a means of attachment. Such dongle embodiments, and their related methods of operation, may allow for retrofitting of legacy gas detectors to provide wireless capabilities.

Abstract: Embodiments relate generally to systems and methods for normalizing the pressure proximate to a gas sensor within a gas detector. A rectifier assembly for use with a gas detector may comprise a flow barrier; a first valve connected to the flow barrier configured to open to normalize the pressure proximate to the gas sensor; a second valve connected to the flow barrier configured to open to allow airflow from the pump toward the gas sensor; and one or more retainer rings configured to position the first valve, second valve, and flow barrier with respect to one another, and configured to position the rectifier assembly within a cavity of the gas detector, wherein the rectifier assembly is configured to be located between a pump and at least one gas sensor of the gas detector; and wherein the rectifier assembly is configured to normalize pressure proximate to the gas sensor.