A measurement system, its assembly and use are disclose. The system may include an instrument for making sensor measurements. The instrument has a substantially cylindrical housing. The shape and size allow the instrument to easily fit in an average hand enabling handheld operation. The housing houses a board stack of electronic boards. These electronics drive an electrical signal in at least one drive channel and measure responses from at least two sensing channels. These responses are provided to a processor for analysis. The instrument has a sensor connector that enables simultaneous electrical and mechanical attachment of an end effector.

The invention relates to a method for condition monitoring of a rope of a hoisting apparatus, and to an arrangement for condition monitoring of a rope of a hoisting apparatus, preferably of an elevator for transporting passengers and/or goods. The arrangement for condition monitoring of a rope of a hoisting apparatus according to the present invention, in which rope comprises one or more conductive load bearing member for bearing the load exerted on the rope in longitudinal direction and extending parallel to each other and to the longitudinal direction of the rope, comprises an at least one eddy current testing probe, placed near said rope for generating an alternating magnetic field, said alternating magnetic field causing eddy currents in said rope, and for detecting a secondary magnetic field being generated by said eddy currents in said rope as eddy current detection data, and an on-line monitoring unit receiving and utilizing said eddy current detection data for on-line condition monitoring of said rope.

A flexible eddy current probe for non-destructive testing of a metallic object may include one or more plus-point coils and a flexible printed circuit having first and second parallel sides, third and fourth parallel sides, and a number of adjacent strips. The strips have first and second ends that are contiguous with the first and second parallel sides, respectively. Each of the strips may contain a pair of coils oriented along the length of the strip, a first coil being proximate to the first end and a second coil being proximate to the second end, and each of the coils is configured to excite an eddy current in the metal object or to sense an eddy current. Each of the strips may also be independently flexible from one another. The eddy current sensor array is configured to be scanned over the metal object.

A flexible eddy current probe for non-destructive testing of a metallic object may include one or more plus-point coils and a flexible printed circuit having first and second parallel sides, third and fourth parallel sides, and a number of adjacent strips. The strips have first and second ends that are contiguous with the first and second parallel sides, respectively. Each of the strips may contain a pair of coils oriented along the length of the strip, a first coil being proximate to the first end and a second coil being proximate to the second end, and each of the coils is configured to excite an eddy current in the metal object or to sense an eddy current. Each of the strips may also be independently flexible from one another. The eddy current sensor array is configured to be scanned over the metal object.

A system and method are provided for inspecting challenging material locations such as holes. The system may include a sensor cartridge (“mandrel”) for hole inspection that has a helical portion to which a sensor array is attached. The radius of the helical portion can be increased or decreased by applying a torque to the helical portion thereby allowing the sensor to be inserted into a hole or pressed against the wall of the hole. A scanner is described to which mandrels can be quickly connected and changed enabling an inspector to quickly switch between different mandrels (e.g., for different holes sizes and sensor configurations). Also disclosed is an inspection procedure and data processing algorithm for performing an inspection. The data processing algorithm utilizes a signature library for enhancing the detection or sizing of features of interest such as cracks. The algorithm and library can account for material edges, various material types.

A system and method are provided for inspecting challenging material locations such as holes. The system may include a sensor cartridge (“mandrel”) for hole inspection that has a helical portion to which a sensor array is attached. The radius of the helical portion can be increased or decreased by applying a torque to the helical portion thereby allowing the sensor to be inserted into a hole or pressed against the wall of the hole. A scanner is described to which mandrels can be quickly connected and changed enabling an inspector to quickly switch between different mandrels (e.g., for different holes sizes and sensor configurations). Also disclosed is an inspection procedure and data processing algorithm for performing an inspection. The data processing algorithm utilizes a signature library for enhancing the detection or sizing of features of interest such as cracks. The algorithm and library can account for material edges, various material types.

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.

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 eddy current flaw detection device according to an embodiment includes: a first exciter/detector that is supplied with alternating current and can induce eddy current in a tested object by generating a magnetic field change in the tested object; a second exciter/detector disposed opposite side of the first exciter/detector sandwiching the tested object therebetween. The second exciter/detector can detect a change in a reactive magnetic field generated by the eddy current. The first and second exciter/detectors each may have a coil including a helical coil wire, and the coil wire of the first exciter/detector may be thicker than the coil wire of the second exciter/detector.

An eddy current flaw detection device according to an embodiment includes: a first exciter/detector that is supplied with alternating current and can induce eddy current in a tested object by generating a magnetic field change in the tested object; a second exciter/detector disposed opposite side of the first exciter/detector sandwiching the tested object therebetween. The second exciter/detector can detect a change in a reactive magnetic field generated by the eddy current. The first and second exciter/detectors each may have a coil including a helical coil wire, and the coil wire of the first exciter/detector may be thicker than the coil wire of the second exciter/detector.