Abstract: Systems and techniques for determining properties of a formation comprising are disclosed. A test tool attached to test string comprising a fluid conduit is deployed to a test position within a wellbore. The deployment includes hydraulically isolating a portion of the wellbore proximate the test tool to form an isolation zone containing the test position. A fluid inflow test is performed within the isolation zone and an initial formation property and a fluid property are determined based on the fluid inflow test. A fluid injection test is performed within the isolation zone including applying an injection fluid through the test string into the isolation zone, wherein the flow rate or pressure of the injection fluid application is determined based, at least in part, on the at least one of the formation property and fluid property, The fluid injection test further includes measuring pressure within the isolation zone to determine a pressure transient associated with the injection of the injection fluid.

Abstract: Disclosed herein are methods and systems for capture and measurement of a target component. A fluid sampling tool for sampling fluid from a subterranean formation may include a sample chamber having a fluid inlet, wherein the sample chamber is lined with a coating of a material that can reversibly hold a target component.

Abstract: A method includes forming a first sealed connection volume between a formation and a first pressure sensor in a borehole and forming a second sealed connection volume between the formation and a second pressure sensor. The second sealed connection volume surrounds the first sealed connection volume. The method further includes lowering a second sealed connection volume pressure to be less than a borehole pressure and acquiring a first measurement using the first pressure sensor before lowering the pressure of the second sealed connection volume, wherein lowering the pressure comprises lowering the pressure to a first lowered outer volume pressure during a first interval. The method further includes acquiring a second measurement using the first pressure sensor, and, in response to a determination that a measurement pattern shows a trend to a formation pressure value, generating a formation property prediction based on the second measurement.

Abstract: Quality factors associated with formation pressure measurements at various depths in the geologic formation are determined based on one or more well logs of formation properties in a geologic formation. A formation testing tool with two or more probes is positioned in a borehole of the geologic formation based on the quality factors. The two or more probes in the borehole perform respective formation pressure measurements, where each formation pressure measurement is performed at a different depth. The formation pressure measurements and the given distance between the two or more probes indicate a formation pressure gradient.

Abstract: A device for coating an interior surface of a housing defining a volume comprising a plurality of reactant gas sources including reactant gases for one or more surface coating processes; first and second closures to sealingly engage with an inlet and outlet of the volume of the housing to provide an enclosed volume; a delivery line fluidically coupled to the first closure and the plurality of reactant gas sources to deliver the reactant gases to the enclosed volume; and an output line fluidically coupled to the second closure to remove one or more reactant gases, byproduct gases, or both from the enclosed volume. A method for coating an interior surface of a housing is also provided.

Abstract: A method and system for performing a pressure test. The method may comprise inserting a formation testing tool into a wellbore to a first location within the wellbore, identifying one or more tool parameters of the formation testing tool, performing a first pre-test with the pressure transducer when the pressure has stabilized to identify formation parameters, inputting the formation parameters and the one or more tool parameters into a forward model, changing the one or more tool parameters to a second set of tool parameters; performing a second pre-test with the second set of tool parameters; and comparing the first pre-test to the second pre-test.

Abstract: Systems and methods for placing well bores and/or portions of completed well systems in a subterranean formation relative to tar mats or other phenomena in the formation are provided. In some embodiments, the methods comprise: identifying a reservoir characteristic associated with a chemical or physicochemical property of a fluid in or proximate to the reservoir characteristic; measuring the property of a fluid in at least a portion of a subterranean formation in two or more locations in the subterranean formation; identifying a variation of the property of the fluid at one or more of the locations in the subterranean formation; and determining a target location or direction for a portion of a well system based at least in part on the variation of the property of the fluid, the well system comprising a borehole penetrating the subterranean formation.

Abstract: A method of evaluating fluid sample contamination is disclosed. A formation tester tool is introduced into a wellbore. The formation tester tool comprises a sensor. Sensor data is acquired from the sensor and a contamination estimation is calculated. A remaining pump-out time required to reach a contamination threshold is then determined.

Abstract: A method for determining the volume of core samples disposed within a sealed pressure vessel, the sealed pressure vessel containing a prefill fluid having a density, the method including determining the internal volume of the pressure vessel; determining the density of the prefill fluid; determining, using at least one of one or more computers, the net density of the core samples disposed within the sealed pressure vessel; determining, using at least one of the one or more computers, the density of one or more earth strata proximate the respective in situ locations of the core samples; and calculating, using at least one of the one or more computers, the volume of the core samples disposed within the sealed pressure vessel. In an exemplary embodiment, the core samples are sealed within the pressure vessel when the pressure vessel is disposed within an oil or gas wellbore.

Abstract: A method for determining the volume of core samples disposed within a sealed pressure vessel, the sealed pressure vessel containing a prefill fluid having a density, the method including determining the internal volume of the pressure vessel; determining the density of the prefill fluid; determining, using at least one of one or more computers, the net density of the core samples disposed within the sealed pressure vessel; determining, using at least one of the one or more computers, the density of one or more earth strata proximate the respective in situ locations of the core samples; and calculating, using at least one of the one or more computers, the volume of the core samples disposed within the sealed pressure vessel. In an exemplary embodiment, the core samples are sealed within the pressure vessel when the pressure vessel is disposed within an oil or gas wellbore.

Abstract: A method, and corresponding system, for formation testing includes establishing a control parameter and a test criterion for testing a formation, providing a formation tester equipped with the control parameter and the test criterion in a well bore at a test location, performing a first formation test, controlling the first formation test using the control parameter and the test criterion, collecting test data from the first formation test, and adjusting the control parameter using the test data. The method may include performing a second formation test, and controlling the second formation test using the adjusted control parameter and the test criterion. The method may include collecting additional test data from the second formation test, and readjusting the control parameter using the additional test data.

Abstract: Systems and methods for accessing a second or additional volume of sampled formation fluids identical to a first volume of formation fluids collected in a primary sample bottle during the downhole sampling process. The second volume can be accessed, extracted and analyzed without having to interfere with the first volume or the integrity of the primary sample. The second volume may be captured in a flowline coupled to the primary sample bottle and accessed using a secondary or mini-sample bottle.

Abstract: A pumping system comprising: a probe to suction a fluid from a fluid reservoir; a pump in fluid communication with said probe; a sensor for detecting phase changes in said pumping system, said sensor in fluid communication with said probe or pump, said sensor generating a sensor signal; a fluid exit from said pumping system, said fluid exit being in fluid communication with said pump; and a variable force check valve located between said probe and said fluid exit.

Abstract: A method of evaluating fluid sample contamination is disclosed. A formation tester tool is introduced into a wellbore. The formation tester tool comprises a sensor. Sensor data is acquired from the sensor and a contamination estimation is calculated. A remaining pump-out time required to reach a contamination threshold is then determined.

Abstract: Methods, systems, and apparatuses for downhole sampling are presented. The sampling system includes a control unit and a housing to engage a conduit. The housing at least partially encloses at least one formation sampler to collect a formation sample. The formation sampler is stored in a sampler carousel. A sampler propulsion system forces the formation sampler into the formation. The propulsion system is in communication with the control unit.

Abstract: A hitch and axle assembly including a support structure detachably securable to a vehicle and an axle assembly. A hitch is mountable on the support structure. The axle assembly includes a primary axle member defining a primary axis. Torsion beam assemblies are coupled to opposite lateral sides of the primary axle member. The torsion beam assemblies each include a torsion member that extends substantially coincident with the primary axis and a lever arm that extends substantially transversely from the torsion member. Wheel assemblies are mounted on a distal portion of the lever arms wherein the wheel assemblies each define an axis of rotation that is parallel and spaced from the primary axis. The two wheel axes are substantially coincident. The torsion bar assemblies may be rotationally adjustable relative to the primary axle to thereby provide for the vertical adjustment of the wheel assemblies.

Abstract: A seal pad comprising a base plate and an expandable material engaged with the base plate. The expandable material comprises an outer surface where a portion of the outer surface is used to form a seal against a borehole wall. A portion of the outer surface of the expandable material is expanded during the sealing against the borehole wall. The seal pad also comprises a retainer for controlling the expansion of the expandable material. The retainer controls the expansion of the expandable material by engaging at least a portion of the outer surface of the expandable material. Thus when the seal is formed by expanding the expandable material, at least a portion of the expandable material is contained by the retainer.