Abstract: A pressure transducer comprises a housing including a body section and at least one end cap at one end of the body section, which are made of piezoelectric crystal, and a piezoelectric resonator in the housing. The body section and the end cap are bonded by an atomic diffusion bonding method.

Abstract: A technique facilitates control over optical transmittance and, in some applications, the technique may be carried out without using moving mechanical parts. A system may comprise a light source and an optical fiber line, e.g. a plurality of optical fiber lines, in optical communication with the light source. An electrochromic device is positioned along each optical fiber line and may be selectively operated via electrical inputs to control optical transmittance along the corresponding optical fiber line. When plural optical fiber lines are employed, the corresponding plurality of electrochromic devices may be operated to also provide control over optical path selection. In fluid analysis operations, at least one sample chamber for receiving fluid samples may be positioned along a corresponding optical fiber line to enable analysis of light directed into the fluid sample as controlled by the corresponding electrochromic device.

Abstract: A technique facilitates control over optical transmittance and, in some applications, the technique may be carried out without using moving mechanical parts. A system may comprise a light source and an optical fiber line, e.g. a plurality of optical fiber lines, in optical communication with the light source. An electrochromic device is positioned along each optical fiber line and may be selectively operated via electrical inputs to control optical transmittance along the corresponding optical fiber line. When plural optical fiber lines are employed, the corresponding plurality of electrochromic devices may be operated to also provide control over optical path selection. In fluid analysis operations, at least one sample chamber for receiving fluid samples may be positioned along a corresponding optical fiber line to enable analysis of light directed into the fluid sample as controlled by the corresponding electrochromic device.

Abstract: A technique facilitates formation evaluation with downhole devices which may include fluid analyzers having atomic absorption spectroscopy (AAS) systems. According to an embodiment, a fluid analyzer of a downhole tool may be positioned in a wellbore penetrating a subterranean formation. The downhole tool comprises a downhole flowline for receiving a sample fluid. Additionally, the fluid analyzer comprises a flowline positioned to receive the sample fluid for analysis by the atomic absorption spectroscopy system. The atomic absorption spectroscopy system has a light source to generate light and to excite atoms of a substance in the sample fluid. The atomic absorption spectroscopy system also comprises a detector to measure how much light has been absorbed by the substance, thus enabling the atomic absorption spectroscopy analysis.

Abstract: A pressure transducer comprises a housing including a body section and at least one end cap at one end of the body section, which are made of piezoelectric crystal, and a piezoelectric resonator in the housing. The body section and the end cap are bonded by an atomic diffusion bonding method.

Abstract: A technique facilitates formation evaluation with downhole devices which may include fluid analyzers having atomic absorption spectroscopy (AAS) systems. According to an embodiment, a fluid analyzer of a downhole tool may be positioned in a wellbore penetrating a subterranean formation. The downhole tool comprises a downhole flowline for receiving a sample fluid. Additionally, the fluid analyzer comprises a flowline positioned to receive the sample fluid for analysis by the atomic absorption spectroscopy system. The atomic absorption spectroscopy system has a light source to generate light and to excite atoms of a substance in the sample fluid. The atomic absorption spectroscopy system also comprises a detector to measure how much light has been absorbed by the substance, thus enabling the atomic absorption spectroscopy analysis.

Abstract: A fluid analyzer of a downhole tool positionable in a wellbore penetrating a subterranean formation is provided. The wellbore has a downhole fluid thereabout. The downhole tool has a downhole flowline for receiving the downhole fluid. The fluid analyzer includes a microflowline fluidly coupled to the downhole flowline to receive the downhole fluid therethrough, a plurality of electrodes positionable in the microflowline to generate an electrical field therebetween and to vaporize the downhole fluid passing therebetween whereby plasma emissions are generated from the downhole fluid, and a plasma detector to measure plasma emissions whereby components of the fluid are detectable.

Abstract: A fluid analyzer of a downhole tool is provided. The downhole tool is positionable in a wellbore penetrating a subterranean formation. The wellbore has a downhole fluid thereabout. The downhole tool has a housing with a flowline therethrough for receiving the downhole fluid. The fluid analyzer includes at least one optical source to pass a light through an optical window and through the downhole fluid in the flowline, at least one photodetector to measure the light passed through the downhole fluid in the flowline, and at least one optical mirror. An optical path of the light extends from the optical source to the photodetector. An optical path length is defined as a length of a portion of the optical path within the flowline. The optical mirror is positionable about the flowline, and has an optical layer selectively passing the light from the optical mirror to the photodetector whereby the optical path length may be varied.

Abstract: A probe of a downhole tool deployable into a wellbore penetrating a subterranean formation is provided. The downhole tool has at least one flowline extendable therein. The formation has a clean fluid therein. The probe includes a base carried by the downhole tool and positionable adjacent a wall of the wellbore, a penetrating inlet carried by the base and having a tip about a sampling end thereof to receive the clean fluid, and an inlet packer. The penetrating inlet is in fluid communication with the at least one flowline, and extendable through the wall of the wellbore a distance into the formation. The inlet packer is inflatably positionable about the penetrating inlet to form a seal with the formation and isolate the tip therein whereby the clean fluid may be drawn from the formation and into the downhole tool.

Abstract: An example system for downhole measurement disclosed herein comprises a tool to be positioned downhole in a formation, the tool comprising an imaging system to determine measurement information from imaging information obtained by sensing light, and an illumination system to control source light to be emitted by the tool. The system also comprises an optical cable to sense an optical field of view that is remote from the tool, the optical cable including an optical fiber bundle comprising a bundle of imaging fibers to convey the imaging information from a sensing end of the optical cable to the imaging system, and a plurality of illumination fibers positioned outside the bundle of imaging fibers, the illumination fibers to convey the source light from the tool to the sensing end of the cable, the illumination fibers to emit the source light to illuminate the optical field of view.

Abstract: A fluid analyzer of a downhole tool positionable in a wellbore penetrating a subterranean formation is provided. The wellbore has a downhole fluid thereabout. The downhole tool has a downhole flowline for receiving the downhole fluid. The fluid analyzer includes a microflowline fluidly coupled to the downhole flowline to receive the downhole fluid therethrough, a plurality of electrodes positionable in the microflowline to generate an electrical field therebetween and to vaporize the downhole fluid passing therebetween whereby plasma emissions are generated from the downhole fluid, and a plasma detector to measure plasma emissions whereby components of the fluid are detectable.

Abstract: A fluid analyzer of a downhole tool is provided. The downhole tool is positionable in a wellbore penetrating a subterranean formation. The wellbore has a downhole fluid thereabout. The downhole tool has a housing with a flowline therethrough for receiving the downhole fluid. The fluid analyzer includes at least one optical source to pass a light through an optical window and through the downhole fluid in the flowline, at least one photodetector to measure the light passed through the downhole fluid in the flowline, and at least one optical mirror. An optical path of the light extends from the optical source to the photodetector. An optical path length is defined as a length of a portion of the optical path within the flowline. The optical mirror is positionable about the flowline, and has an optical layer selectively passing the light from the optical mirror to the photodetector whereby the optical path length may be varied.

Abstract: An example system for downhole measurement disclosed herein comprises a tool to be positioned downhole in a formation, the tool comprising an imaging system to determine measurement information from imaging information obtained by sensing light, and an illumination system to control source light to be emitted by the tool. The system also comprises an optical cable to sense an optical field of view that is remote from the tool, the optical cable including an optical fiber bundle comprising a bundle of imaging fibers to convey the imaging information from a sensing end of the optical cable to the imaging system, and a plurality of illumination fibers positioned outside the bundle of imaging fibers, the illumination fibers to convey the source light from the tool to the sensing end of the cable, the illumination fibers to emit the source light to illuminate the optical field of view.

Abstract: An apparatus disclosed herein includes a pliable filter and a brace coupled to the filter. The example apparatus further includes a first portion of a housing coupled to a second portion of the housing to hold the filter across an inlet of a first fluid flow passageway, which is in fluid communication with a second fluid flow passageway via the inlet. A seal is disposed between the brace and the housing and surrounds the inlet.

Abstract: A pressure transducer for high-pressure measurements comprising a housing and a piezoelectric resonator located in the housing, wherein the resonator comprises double rotation cut piezoelectric material configured or designed for vibrating in the fundamental tone of dual modes of the fast and slow thickness-shear vibrations.

Abstract: A heat switch for remote self-contained gas chromatography is disclosed. The device mechanically separates a hot or cold reservoir from the chromatography column when heating or cooling is not needed. The column needs a cooling system to obtain initial temperatures below ambient. At other times the column needs to be heated to relatively high temperatures, during which time the cooling system is preferably detached. The heat switch allows for rapid temperature changes while minimizing the peak cooling power requirement.

Abstract: A self-contained micro-scale gas chromatography system that includes a plurality of gas chromatography components arranged on a micro-fluidic platform with nearly zero dead volume “tubeless” fluidic connections for the gas chromatography components. The micro-fluidic platform includes a plurality of flow channels that provide fluid flow paths for a sample, carrier gas and waste gas through and among the micro-fluidic platform and the plurality of gas chromatography components. The gas chromatography components may include a micro-scale gas chromatography column that is implemented as a MEMS device and includes embedded heating and cooling elements. The system may also include an on-board supply of carrier gas and on-board waste management, as well as a thermal management scheme making the system suitable for use in oil and gas wells and also other remote environments.

Abstract: A self-contained micro-scale gas chromatography system that includes a plurality of gas chromatography components arranged on a micro-fluidic platform with nearly zero dead volume “tubeless” fluidic connections for the gas chromatography components. The micro-fluidic platform includes a plurality of flow channels that provide fluid flow paths for a sample, carrier gas and waste gas through and among the micro-fluidic platform and the plurality of gas chromatography components. The system may also include an on-board supply of carrier gas and on-board waste management, as well as a thermal management scheme making the system suitable for use in oil and gas wells and also other remote environments.

Abstract: A pressure transducer for high-pressure measurements comprising a housing and a piezoelectric resonator located in the housing, wherein the resonator comprises double rotation cut piezoelectric material configured or designed for vibrating in the fundamental tone of dual modes of the fast and slow thickness-shear vibrations.

Abstract: A heat switch for remote self-contained gas chromatography is disclosed. The device mechanically separates a hot or cold reservoir from the chromatography column when heating or cooling is not needed. The column needs a cooling system to obtain initial temperatures below ambient. At other times the column needs to be heated to relatively high temperatures, during which time the cooling system is preferably detached. The heat switch allows for rapid temperature changes while minimizing the peak cooling power requirement.