Abstract: A gas sampling device is disclosed. The gas sampling device includes a first block having at least a first opening. The first block includes at least a first passageway terminating at the first opening. The first opening may be in an exterior face of the first block. The gas sampling device includes a second block having at least a second opening. The second block includes at least a second passageway terminating at the first opening. The second opening may be in the exterior face of the second block. The first block and the second block may be adjacent and in contact with each other. The first passageway and the second passageway form a flow path, wherein the first block and the second block abut and contact each other, and the first opening and the second opening are aligned.

Abstract: An analyzer instrument, gas sampling and analyzing system, and method are disclosed for detecting water vapor in gas using tunable diode laser absorption spectroscopy at a wavelength of 1871 nm plus or minus 2 nm.

Abstract: A sampling device for a gas comprises a block member that includes a gas passageway that defines a flow path for the gas through the block member that has a length less than 36 inches. A liquid collection chamber within the block member along the flow path has therein a deflection plate that directs any liquid in the gas onto a surface of the plate downward into a lower sink zone of the chamber. The chamber includes a porous membrane along the flow path that acts as a barrier to liquid, allowing gas to flow through the membrane and into a passageway segment downstream of the membrane. A pair of mirrors at opposed ends of a light collection block are shaped to reflect multiple passes of light between the mirrors. At one end of the light collection block is a lens that focuses light on the mirror at the other end of the light collection block. A light detector near one end of the light collection block collects light after multiple reflections of the light off the mirrors.

Abstract: A gas sensor comprises an electrically conductive housing including a shelf member and a chamber containing an electrolyte. A conductive cathode mounted on the shelf member has a plurality of holes therein and a conductive tail element. A gas permeable membrane overlying the cathode prevents electrolyte from escaping the chamber but allows gas to permeate the membrane. An anode within the chamber is in electrical contact with the electrolyte and the conductive housing. The tail element is adapted to be connected to the anode through an electrical circuit including the conductive housing.

Abstract: A gas sensor comprises an electrically conductive housing including a shelf member and a chamber containing an electrolyte. A conductive cathode mounted on the shelf member has a plurality of holes therein and a conductive tail element. A gas permeable membrane overlying the cathode prevents electrolyte from escaping the chamber but allows gas to permeate the membrane. An anode within the chamber is in electrical contact with the electrolyte and the conductive housing. The tail element is adapted to be connected to the anode through an electrical circuit including the conductive housing.

Abstract: An instrument provides a quantitative measurement of an analyte in a gas. It includes a detection cell that provides an indication of an amount of analyte present in the gas, and a valve having a closed position, a sample gas position, and a calibration gas position. There is a calibration gas inlet orifice in communication with a gas outlet through a first flow path including the valve and the detection cell, and a sample gas inlet orifice in communication with the gas outlet through a second flow path including a scrubber, the valve, and the detection cell. Two orifices of different sizes, a sample gas orifice along the second flow path, and a bypass orifice positioned between the sample gas orifice and the gas outlet, prevent a build up of excessive pressure in the instrument when the valve is in the closed position or the calibration gas position.

Abstract: An instrument provides a quantitative measurement of an analyte in a gas. It includes a detection cell that provides an indication of an amount of analyte present in the gas, and a valve having a closed position, a sample gas position, and a calibration gas position. There is a calibration gas inlet orifice in communication with a gas outlet through a first flow path including the valve and the detection cell, and a sample gas inlet orifice in communication with the gas outlet through a second flow path including a scrubber, the valve, and the detection cell. Two orifices of different sizes, a sample gas orifice along the second flow path, and a bypass orifice positioned between the sample gas orifice and the gas outlet, prevent a build up of excessive pressure in the instrument when the valve is in the closed position or the calibration gas position.

Abstract: An instrument provides a quantitative measurement of an analyte in a gas. It includes a detection cell that provides an indication of an amount of analyte present in the gas, and a valve having a closed position, a sample gas position, and a calibration gas position. There is a calibration gas inlet orifice in communication with a gas outlet through a first flow path including the valve and the detection cell, and a sample gas inlet orifice in communication with the gas outlet through a second flow path including a scrubber, the valve, and the detection cell. Two orifices of different sizes, a sample gas orifice along the second flow path, and a bypass orifice positioned between the sample gas orifice and the gas outlet, prevent a build up of excessive pressure in the instrument when the valve is in the closed position or the calibration gas position.