A method and a lateral entry guide tool for deploying a work string in a wellbore defining a window and a lateral wellbore extending from the window are described. The work string and the tool are run through the wellbore to a distance above the window. A locator subassembly is activated to detect the window. The tool is run through the wellbore in a downhole direction from the distance above the window past the window. After the locator subassembly indicates that the tool is past the window, a window entry depth is determined based a depth at which the window was detected. The work string is pulled back to position the tool at the window entry depth. A positioning subassembly is activated. The work string is run through the window while adjusting and calibrating the positioning subassembly as the work string pass through the window into the lateral wellbore.

A method for determining a pressure profile in a subterranean formation is described. The method includes drilling a wellbore in the subterranean formation; lowering a logging tool into the wellbore to measure resistivity values as a function of depth along the wellbore; identifying a plurality of porous zones from the wellbore based on petrophysical logs; converting the measured resistivity values to an amount of total dissolved solids for each of the plurality of identified porous zones; converting the amount of total dissolved solids to a pore fluid density; calculating a pressure based on a sum of the pore fluid densities derived along a length of the well; and generating a depth-based pressure profile.

A method for determining a pressure profile in a subterranean formation is described. The method includes drilling a wellbore in the subterranean formation; lowering a logging tool into the wellbore to measure resistivity values as a function of depth along the wellbore; identifying a plurality of porous zones from the wellbore based on petrophysical logs; converting the measured resistivity values to an amount of total dissolved solids for each of the plurality of identified porous zones; converting the amount of total dissolved solids to a pore fluid density; calculating a pressure based on a sum of the pore fluid densities derived along a length of the well; and generating a depth-based pressure profile.

A wireline width measuring apparatus and associated method which may be used to measure static and dynamic fracture width in fractures used for energy storage, water injection, or hydrocarbon production. In one embodiment, the method comprises determining a depth of the formation fracture, determining the depth of the bottom of the wellbore, positioning a caliper tool string comprising a caliper apparatus at the bottom of the wellbore, wherein the caliper apparatus is positioned at a depth capable of measuring movement of a window cut into a casing of the wellbore at the depth of the formation fracture, inflating the fracture by injecting a fluid into the fracture, uninflating the fracture by producing the fluid from the fracture, and measuring movement of the window cut into the wellbore while the fracture is inflated and uninflated.

A method for performing a maintenance operation of a well in an oil/gas field is disclosed. The method includes identifying an extent of corrosion deposit of the well, predicting, using a descaling model of the oil/gas field and based on the extent of corrosion deposit, expected descaling metal loss in a tubular of the well, calculating, based on the expected descaling metal loss, a tubular burst/collapse pressure for a predicted thickness of the tubular, comparing the tubular burst/collapse pressure against a well operating pressure to generate a comparison result, and performing the maintenance operation of the well based on the comparison result.

A well tool can be used in a wellbore that can measure characteristics of an object in the wellbore. The well tool includes an ultrasonic transducer for generating an ultrasonic wave in a medium of the wellbore. The ultrasonic transducer includes a front layer, a rear layer, backing material coupled to the rear layer, and piezoelectric material coupled to the front layer and to the backing material. The rear layer can improve signal-to-noise ratio of the transducer in applications such as imaging and caliper applications.

Deconvolution-based processing of ultrasonic waveforms enables robust calculation of two-way travel time for an ultrasonic caliper, particularly in the presence of multiple, proximal reflectors (e.g., mud cake, formation, casing, cement, etc.).

The present disclosure introduces an MFC module for use in a tubular extending into a subterranean formation. The MFC module includes a tool body having slots that each include a receptacle. The MFC module also includes measuring fingers each independently rotatable within a corresponding one of the slots via a corresponding pivot formed by complementary linking portions of the measuring finger and the receptacle of the corresponding slot. The linking portions of the receptacle are situated on opposing side walls of the receptacle. The MFC modules also includes linear displacement sensors each operable for sensing an orientation of a corresponding one of the measuring fingers relative to the tool body.

The present disclosure introduces an MFC module for use in a tubular extending into a subterranean formation. The MFC module includes a tool body having slots that each include a receptacle. The MFC module also includes measuring fingers each independently rotatable within a corresponding one of the slots via a corresponding pivot formed by complementary linking portions of the measuring finger and the receptacle of the corresponding slot. The linking portions of the receptacle are situated on opposing side walls of the receptacle. The MFC modules also includes linear displacement sensors each operable for sensing an orientation of a corresponding one of the measuring fingers relative to the tool body.

A method is disclosed that includes measuring an inner diameter (ID) of a tubular at least at a plurality of points along an inner circumference of the tubular, at a predetermined axial distance from an end of the tubular, to yield a first set of measurements. A computer processor is used to: create a tubular profile from the first set of measurements, wherein the tubular profile represents a unique identification code of the tubular; save the profile; and thereafter identify the tubular. The tubular is identified via: receiving a second set of measurements of the ID of the tubular from at least at a plurality of points along an inner circumference of the tubular, at the predetermined axial distance from the end of the tubular; and comparing the second set of measurements with the saved tubular profile to identify the tubular.