Abstract: A gas detecting system includes a detector having a housing, a sensor module, a controller, energy storage, and a photoelectric conversion component. The photoelectric conversion component may be mounted in or on the housing to provide electrical power to the energy storage while the energy storage powers the detector. Accordingly, the photoelectric conversion component can extend working time of the detector beyond the normal capabilities of the energy storage alone. The gas detecting system may further include a base station that provides light for charging or operation of the detector and that communicates with the detector for programming of the detector and processing of measurement data.

Abstract: A gas detecting system includes a detector having a housing, a sensor module, a controller, energy storage, and a photoelectric conversion component. The photoelectric conversion component may be mounted in or on the housing to provide electrical power to the energy storage while the energy storage powers the detector. Accordingly, the photoelectric conversion component can extend working time of the detector beyond the normal capabilities of the energy storage alone. The gas detecting system may further include a charger that provides concentrated light for charging or operation of the detector.

Abstract: A gas detecting system includes a detector having a housing, a sensor module, a controller, energy storage, and a photoelectric conversion component. The photoelectric conversion component may be mounted in or on the housing to provide electrical power to the energy storage while the energy storage powers the detector. Accordingly, the photoelectric conversion component can extend working time of the detector beyond the normal capabilities of the energy storage alone. The gas detecting system may further include a charger that provides concentrated light for charging or operation of the detector.

Abstract: An oxygen sensor includes a solid polymer electrolyte, e.g., on an acid treated Nafion membrane and uses a diffusion-limited fuel cell type reactions. The sensor avoids electrolyte leakage and avoids consumption of electrodes. In different configurations, a counter or reference electrode can be on the same or the opposite side of the electrolyte as a sensing electrode. An insert limits and controls oxygen diffusion into a sensing chamber containing the sensing electrode that catalyzes reduction of oxygen. Applying appropriate bias voltages to the reference and sensing electrodes causes an output current of the sensing electrode to be proportional to the rate of oxygen consumption based on Frick's law under a diffusion-limited mode. The output current can be measured, e.g., using a resistor to convert the current to a voltage signal.

Abstract: A photo-ionization detector having an adjustable drive power for a UV lamp implements a calibration operation that determines measurement signals for a series of drive power levels and based on the resulting measurement signals selects one or more drive power levels for normal operation of the PID. The calibration operation permits use of UV lamps having a wider range of performance levels and thereby improves manufacturing yields and extends the useful life of the PID. During normal operation, the PID further fine-tunes the drive power level to compensate for expected or measured degradation in lamp performance. Accordingly, between calibrations, the PID maintains a more uniform UV intensity for more accurate measurements. To expand the measurement range of the PID, the calibration process can select two or more power levels for use when measuring different gas concentrations.

Abstract: A photo-ionization detector (PID) including two detection units controls gas flows through the ionization chambers of the detection units for real-time self-cleaning and measurement. Operation of the PID can include flowing gas through the ionization chamber of one detection unit to measure the volatile gas concentration while stopping gas flow through the ionization chamber of the other detection unit. A UV lamp converts oxygen contained in the closed ionization chamber to ozone, which removes contamination in the closed ionization chamber, Continuous gas flows can alternate between one ionization chamber to the other. Alternatively, a PID with only one gas detection unit intermittently interrupts the flow of the ambient gas in the ionization chamber.

Abstract: A photo-ionization detector (PID) includes a microprocessor, a first gas detection unit, and a second gas detection unit. The microprocessor controls the first and second gas detection units such that ambient gas always flows through the ionization chamber of one of the gas detection units while the flow of the ambient gas is closed in the ionization chamber of the other one of the gas detection units. The UV lamp converts oxygen in the closed ambient gas to ozone, which removes contamination in the ionization chamber with the closed ambient gas. When the PID includes only one gas detection unit, the microprocessor controls the gas detection unit such that the flow of the ambient gas in the ionization chamber is intermittently interrupted.

Abstract: An NDIR sensor includes a cylindrical metallic tube, a printed circuit board platform that fits into one end of the tube, a diffusion filter that fits into the opposite end of the tube, and an optical system. The optical system includes an infrared source on the platform, a mirror on the inner wall of the tube so as to reflect and focus the infrared light from the infrared source, and a detector assembly that receives the infrared light after reflection. The gas sensor may further include a partition between the infrared source and the detector assembly, a removable filter on the diffusion filter, connecting pins attached to the platform, and a sealing layer formed under the platform. The detector assembly includes a signal detector and a reference detector. A first and second bandpass filters are respectively formed on the signal and reference detectors.

Abstract: A multiple-channel photo-ionization detector (PID) determines the concentrations of specific gases or classes of gases. The PID includes a UV lamp, an optical window which is divided into multiple zones with each zone producing a UV light beam having a distinctive maximum photon energy. The ionization chamber of the PID includes multiple ion detectors. The PID measures ionization currents and concentrations of gases ionizable by each UV light beam. A method of determining the concentrations and/or identifications of the individual component gases uses differences and/or ratios of measured concentrations or currents.

Abstract: A dual-channel photo-ionization detector (PID) and a method for calculating the gas concentration in the PID are disclosed. The PID includes a UV light source which produces a UV light to ionize a gas, first and second identical ion detectors for measuring first and second currents including ion, and a UV shield which differentially shields the ion detectors from the UV light. The differential shielding of the ion detectors enables the PID to differentiate between current caused by ions and current caused by the photoelectric effect of the UV light. The detector measures a concentration of the gas irrespective of a variation of an intensity of the UV light. A heater in the PID stabilizes the temperature for measurements and prevents condensation in the PID.

Abstract: A photo-ionization detector (PID) includes an ultraviolet (UV) lamp that transmits UV light into an ionization chamber to ionize volatile gases. An ion detector in the ionization chamber includes interdigital electrodes that collect resulting ions using an electrical field perpendicular to the UV light propagation. A pump in the PID circulates gases through the ionization chamber in a direction perpendicular to the electrical field and to the UV light propagation. The PID additionally provides a UV monitor having interdigital electrodes that release electrons when struck by the UV light. The size of a monitor current in the UV monitor indicates the intensity of the UV light. The UV monitor is in a UV monitor chamber that protects the UV monitor from exposure to the ionized gases and improves the accuracy of UV intensity measurements.