Abstract: Methods, devices, and systems are provided for analyzing the moisture content in natural gas. In one embodiment, a portable moisture analyzer system is provided and can include a moisture analyzer and a housing. The moisture analyzer can include a tunable diode laser absorption spectrometer (TDLAS) and a natural gas sample conditioning system. The TDLAS can be configured to detect water vapor content within a natural gas sample. The sample conditioning system can be in fluid communication with the TDLAS and can be configured to condition at least one of temperature, flow rate, and pressure of a natural gas sample. The housing can be configured to receive the moisture analyzer therein and to protect the moisture analyzer from vibration and/or shock.

Abstract: Methods, devices, and systems are provided for analyzing the moisture content in natural gas. In one embodiment, a portable moisture analyzer system is provided and can include a moisture analyzer and a housing. The moisture analyzer can include a tunable diode laser absorption spectrometer (TDLAS) and a natural gas sample conditioning system. The TDLAS can be configured to detect water vapor content within a natural gas sample. The sample conditioning system can be in fluid communication with the TDLAS and can be configured to condition at least one of temperature, flow rate, and pressure of a natural gas sample. The housing can be configured to receive the moisture analyzer therein and to protect the moisture analyzer from vibration and/or shock.

Abstract: Methods, devices, and systems are provided for analyzing the moisture content in natural gas. In one embodiment, a portable moisture analyzer system is provided and can include a moisture analyzer and a housing. The moisture analyzer can include a tunable diode laser absorption spectrometer (TDLAS) and a natural gas sample conditioning system. The TDLAS can be configured to detect water vapor content within a natural gas sample. The sample conditioning system can be in fluid communication with the TDLAS and can be configured to condition at least one of temperature, flow rate, and pressure of a natural gas sample. The housing can be configured to receive the moisture analyzer therein and to protect the moisture analyzer from vibration and/or shock.

Abstract: Methods, devices, and systems are provided for analyzing the moisture content in natural gas. In one embodiment, a portable moisture analyzer system is provided and can include a moisture analyzer and a housing. The moisture analyzer can include a tunable diode laser absorption spectrometer (TDLAS) and a natural gas sample conditioning system. The TDLAS can be configured to detect water vapor content within a natural gas sample. The sample conditioning system can be in fluid communication with the TDLAS and can be configured to condition at least one of temperature, flow rate, and pressure of a natural gas sample. The housing can be configured to receive the moisture analyzer therein and to protect the moisture analyzer from vibration and/or shock.

Abstract: An electronic housing assembly is formed with an environmental seal (20), EMI control (56) and a good thermal coupling (44, 46) made between enclosed hot electric components (48, 50) and an exterior heat sink (52, 54).

Abstract: A light emitting diode bulb (10) has a base (12), with a printed circuit board (14) contained therewithin, a plurality of electrical connectors (16) having a first end (18) mounted upon the circuit board (14) and a second end (20) extending away from the base (12) in a direction normal thereto. Each of the electrical connectors (16) comprises at least a first electrically conductive plate (16a), a contiguous insulator (16b) and a second electrically conductive plate (16c). A light emitting diode (22) is electrically connected between the at least a first electrically conductive plate (16a) and the second electrically conductive plate (16c) adjacent the second end (20) on each of the plurality of electrical connectors (16).

Abstract: A low insertion force seating grommet (10) has a hollow body (12) arrayed along a longitudinal axis (14). The body (12) has a wide end (16) and a narrow end (18) connected by an intermediate portion (20). The narrow end (18) has a cylindrical aperture (18a) and the wide end (16) has a cup-shaped aperture (16a). A flange (22) surrounds the wide end (16) and is provided with a wall-opening engaging portion (24). Longitudinally extending relief grooves (26) are formed on the internal surface (28) of the cup-shaped aperture (18a).

Abstract: A low insertion force seating grommet assembly (10a) has a hollow body (12) arrayed along a longitudinal axis (14). The body (12) has a wide end (16) and a narrow end (18) connected by an intermediate portion (20). The narrow end (18) has a cylindrical aperture (18a) and the wide end (16) has a cup-shaped aperture (16a). A flange (22) surrounds the wide end (16) and is provided with a wall-opening engaging portion (24). Longitudinally extending relief grooves (26) are formed on the internal surface (28) of the cup-shaped aperture (18a). A cable (32) is frictionally engaged in the cylindrical aperture and penetrates the cup-shaped aperture. A cover (30) closes the cup-shaped aperture. The cable enters the cover along the longitudinal axis and exits the cover at an angle of 90 degrees relative to the longitudinal axis.

Abstract: An LED light source (10) has a housing (12) with a base (14) and a hollow core (16) projecting from the base (14), the core (16) being substantially conical. A first printed circuit board (18) is fitted to the base (14). A second printed circuit board (20) is fitted to the narrow end (22) of the core (16), the second printed circuit board (20) having at least one LED (24) operatively fixed thereto. A plurality of electrical conductors 26 is provided having proximal ends (28) attached to and extending from the second printed circuit board (20) and distal ends (30) attached to and projecting through the first printed circuit board (18). A cap (32) is fitted over the second printed circuit board (20) and a heat sink (34) is attached to the base (14) and in contact with the distal ends (30) of the electrical conductors (26). The housing (12) is provided with flanges for engaging a suitable opening in the rear of a reflector.