A method, apparatus, and system for scanning an elongate structure. A scanner in a scanning system is moved axially along the elongate structure using a translating structure in the scanning system. The elongate structure is scanned axially using an x-ray beam emitted by the scanner as the scanner moves axially along the elongate structure to perform an axial scan. The x-ray beam has a first orientation. A location on the elongate structure having an inconsistency is detected while scanning the elongate structure axially. The elongate structure is scanned at the location with the x-ray beam in a second orientation.

A method for operating a measurement system (100) comprises: generating a beam of electromagnetic radiation (25) directed along a central ray (27) using a radiation source (19); moving the radiation source (19) relative to an object region (35) so that the central ray (27) is directed onto a radiation detector (31) during the movement; wherein the moving of the radiation source (19) relative to the object region (35) comprises: rotating the radiation source (19) about a first axis of rotation (D1), wherein the radiation source (19) is disposed eccentrically to the first axis of rotation (D1); rotating the radiation source (19) about a second axis of rotation (D2), wherein the first axis of rotation (D1) and the second axis of rotation (D2) together enclose an acute angle () amounting to at most 80.

A method for operating a measurement system (100) comprises: generating a beam of electromagnetic radiation (25) directed along a central ray (27) using a radiation source (19); moving the radiation source (19) relative to an object region (35) so that the central ray (27) is directed onto a radiation detector (31) during the movement; wherein the moving of the radiation source (19) relative to the object region (35) comprises: rotating the radiation source (19) about a first axis of rotation (D1), wherein the radiation source (19) is disposed eccentrically to the first axis of rotation (D1); rotating the radiation source (19) about a second axis of rotation (D2), wherein the first axis of rotation (D1) and the second axis of rotation (D2) together enclose an acute angle (?) amounting to at most 80?.

Systems and methods are provided for physically labeling structural features, such as weld joints in a pipeline, with pattern-based codes that uniquely identify respective features. The systems and methods are also provided for identifying the features based on imagery of the codes captured during subsequent inspection of the weld joints. In particular, the weld joints can be uniquely identified by encoding measured geographic coordinates within two distinguishable circular patterns that correspond to latitude and longitude, respectively. In addition, the pattern-based codes can be applied to respective weld joints using a contrast material such that the codes are revealed in the images of the weld joints captured during inspection. Furthermore, the systems and methods include analyzing the images captured during inspection to identify the inspected weld joints for the purpose of verifying that each weld joint was properly inspected in the field.

A faulted condition determination method is designed to detect a chromium content and a nickel content in a predetermined boundary region proximate to a boundary between a high-strength ferrite steel and a weld material in a welded joint in which the high-strength ferrite steel and another steel are welded together using the weld material containing nickel and to thereby determine the faulted condition of the predetermined boundary region based on the chromium content and the nickel content. Accordingly, it is possible to appropriately determine the faulted condition of welding of a replacement part in which a high-strength ferrite steel and another steel are welded together using a nickel-based weld material.

A method for use with a subterranean well can include positioning an x-ray unit so that x-rays emitted by the x-ray unit scan a tubular string, displacing the tubular string relative to the x-ray unit, and identifying a threaded connection in the tubular string. A system can include a torque application device configured to apply torque to a threaded connection in a tubular string, and an x-ray unit configured to project x-rays toward the tubular string.

The present invention relates to a method to determine geometrical parameters of an object under study by radiography, the object can be described geometrically, wherein intercepts that go through the material of the object under study can be determined from a projection of the objecte.g. a tubeimaged by an X- or gamma-radiation source if exposition data of the radiographic image are available. These intercepts that go through the material of the objecti.e. the intercept curvesallow that the object under studye.g. the tubehave a dimension that is larger than the dimension of the device (film/detector) used to take the radiographic image. During the course of said method, the source of radiation, the object under study and the device (film/detector) used to take the radiographic image are in a fixed position.

Systems and methods are provided for physically labeling structural features, such as weld joints in a pipeline, with pattern-based codes that uniquely identify respective features. The systems and methods are also provided for identifying the features based on imagery of the codes captured during subsequent inspection of the weld joints. In particular, the weld joints can be uniquely identified by encoding measured geographic coordinates within two distinguishable circular patterns that correspond to latitude and longitude, respectively. In addition, the pattern-based codes can be applied to respective weld joints using a contrast material such that the codes are revealed in the images of the weld joints captured during inspection. Furthermore, the systems and methods include analyzing the images captured during inspection to identify the inspected weld joints for the purpose of verifying that each weld joint was properly inspected in the field.

A method, apparatus, and system for scanning an elongate structure. A scanner in a scanning system is moved axially along the elongate structure using a translating structure in the scanning system. The elongate structure is scanned axially using an x-ray beam emitted by the scanner as the scanner moves axially along the elongate structure to perform an axial scan. The x-ray beam has a first orientation. A location on the elongate structure having an inconsistency is detected while scanning the elongate structure axially. The elongate structure is scanned at the location with the x-ray beam in a second orientation.

A method for generating a recommendation based on welding defects. The method includes receiving, from an imaging device, an inspection image of a target object, determining an inspection thickness of the target object based on the inspection image, converting into a multilevel thresholded thickness map based on a particular sensitivity, determining a defect of the target object based on the inspection thickness, quantifying and characterizing the defect, determining a critical level of the defect of the target object by comparing a parameter of the defect to a critical threshold and generating a recommendation based on the critical level.