An eddy current instrument for non-destructive testing of a tubular metallic object, the instrument comprising a probe head with probe coils and probe coil signal conditioning and analog to digital conversion electronics and a probe connector module with a processor and probe coil excitation signal generation electronics. The probe connector processor is configured to interface to an external computing device, which may be a personal computer. The probe head and probe connector module may be connected by a rigid shaft or by a flexible coupling.

Embodiments of an inline inspection (“ILI”) tool (10) of this disclosure include a plurality of composite field systems (20) arranged circumferentially about the body of the ILI tool, each composite field system including multiple magnetic circuits (60) to produce a composite or resultant angled field © relative to the target, along with a sensor array or circuit (40) configured for magnetic flux leakage (“MFL”) or magnetostrictive electro-magnetic acoustic transducers (“EMAT”) implementations. In embodiments, the pole magnets (61) of the magnetic circuits are oriented in the axial direction of the tool body rather than in the direction of the resultant angled field. The same is true of the sensors (43). This composite field system approach provides options to design geometries that were not previously possible in prior art single-circuit helical MFL designs and EMAT designs.

Embodiments of an inline inspection (“ILI”) tool (10) of this disclosure include a plurality of composite field systems (20) arranged circumferentially about the body of the ILI tool, each composite field system including multiple magnetic circuits (60) to produce a composite or resultant angled field © relative to the target, along with a sensor array or circuit (40) configured for magnetic flux leakage (“MFL”) or magnetostrictive electro-magnetic acoustic transducers (“EMAT”) implementations. In embodiments, the pole magnets (61) of the magnetic circuits are oriented in the axial direction of the tool body rather than in the direction of the resultant angled field. The same is true of the sensors (43). This composite field system approach provides options to design geometries that were not previously possible in prior art single-circuit helical MFL designs and EMAT designs.

A device and procedures perform an inspection of steel wire ropes and steel chains. The device is formed from a minimum of two contactless housing segments that are positioned around a test specimen and are equidistant connected when open. The housing segments have an internal normal surface that is radial and center-oriented when closed. The housing segments also form a supporting housing for all of the other components, and being connected on one of its longitudinal sides as a minimum. The connection being realized by moving connecting pieces for defining the clearance, rotation axis and the opening angles of each of the housing segments and which have a suitable closing mechanism positioned on a freely definable pair of longitudinal sides of the housing segment for the purpose of locking when in a closed condition and in order to apply a required pressing force.

Disclosed herein is a differential probe, a testing device having at least one such differential probe, and a method for producing the same. The differential probe has a first half-probe and a second half-probe, at least one conductor loop pair having a conductor loop of each half-probe being shaped mirror-inverted relative to each other and, in respect of a mirror-inverted arrangement thereof on respective sides of a mirror plane. The conductor loops are oriented parallel to the mirror plane, are arranged offset relative to each other in an offset direction, also parallel to the mirror plane, wherein the conductor loops overlap in part in the direction normal to the mirror plane.

An inspection system for a plurality of separable inspection objects, including a feed device for the plurality of inspection objects, a conveying device for the plurality of inspection objects, an inspection unit and an ejecting device. The feed device is configured and disposed such that the plurality of inspection objects can be fed by the feed device to a feed position of the conveying device. The conveying device includes a plurality of receptacles, each receptacle is configured and disposed such that exactly one inspection object of the plurality of inspection objects can be conveyed along a conveying path in said receptacle and that two respective inspection objects from the plurality of inspection objects have a spacing along the conveying path that is defined by the plurality of receptacles. The inspection unit is disposed at an inspection position on the conveying path.

An inspection system for a plurality of separable inspection objects, including a feed device for the plurality of inspection objects, a conveying device for the plurality of inspection objects, an inspection unit and an ejecting device. The feed device is configured and disposed such that the plurality of inspection objects can be fed by the feed device to a feed position of the conveying device. The conveying device includes a plurality of receptacles, each receptacle is configured and disposed such that exactly one inspection object of the plurality of inspection objects can be conveyed along a conveying path in said receptacle and that two respective inspection objects from the plurality of inspection objects have a spacing along the conveying path that is defined by the plurality of receptacles. The inspection unit is disposed at an inspection position on the conveying path.

Apparatus and method for detecting flaws in a wall of a metallic pipe containing a fluid are disclosed. The apparatus includes: a plurality of sensors distributed around an inner circumference of the metallic pipe, for sensing magnetic field signals from the metallic pipe; a collapsible supporting structure, including a plurality of supporting petals, at a front side of the plurality of sensors for supporting the apparatus; a sail mounted on and extended from bottom ends of the plurality of supporting petals, when the plurality of supporting petals are in an extended state, the sail is expanded to form a shape capable for containing the fluid; a processing module receiving sensed data from the plurality of sensors; and one or more battery modules for electrically powering the plurality of sensors and the processing module.

Apparatus and method for detecting flaws in a wall of a metallic pipe containing a fluid are disclosed. The apparatus includes: a plurality of sensors distributed around an inner circumference of the metallic pipe, for sensing magnetic field signals from the metallic pipe; a collapsible supporting structure, including a plurality of supporting petals, at a front side of the plurality of sensors for supporting the apparatus; a sail mounted on and extended from bottom ends of the plurality of supporting petals, when the plurality of supporting petals are in an extended state, the sail is expanded to form a shape capable for containing the fluid; a processing module receiving sensed data from the plurality of sensors; and one or more battery modules for electrically powering the plurality of sensors and the processing module.

A system for magnetically inspecting a metallic component uses a manipulator configured to manipulate a relative position between a part fixture that holds the metallic component and a probe fixture that holds a magnetic probe, thereby causing the probe tip to trace an inspection route along the surface of the metallic component so that the probe tip contacts the metallic component such that an angular difference between the probe axis and a vector normal to the surface is less than a predetermined angle delta. The magnetic probe has a probe tip that measures magnetic permeability of the metallic component along the inspection route, which the controller receives. A method of performing the magnetic inspection is also disclosed.