Disclosed herein is a concrete material comprising between 0.5% and 10% ferromagnetic fibres. Also disclosed herein is a method for measuring the strain state of a concrete material, the method comprising forming solid concrete containing between 0.5% and 10% ferromagnetic fibres in a random distribution throughout the concrete, applying an oscillating EM current to the concrete, and detecting the associated EM fields within the concrete. Also disclosed herein is the use of an oscillating EM current field to measure the strain state within a concrete material comprising between 0.5% and 10% ferromagnetic fibres.

A magnetic particle carrier fluid recovery system includes at least one filter and a fluorescence reducer in fluid communication with contaminated magnetic particle carrier fluid. The filter(s) removes particulate matter less than 1 micron in size. The fluorescence reducer removes soluble fluorescent compounds from the carrier fluid causing background fluorescence contamination. A pump circulates the carrier fluid from a reservoir of contaminated fluid, through the system, and back to the reservoir. A cleaning loop runs the carrier fluid through the filter(s) and fluorescence reducer to remove contaminants to levels acceptable for new magnetic particle carrier fluid. A testing loop may be included that bypasses the filter(s) and fluorescence reducer. A valve may be actuated to toggle between the testing loop and cleaning loop for selective cleaning or use of the carrier fluid for MPI testing. The system may be integrated with an MPI station or may be independent and mobile.

A magnetic particle carrier fluid recovery system includes at least one filter and a fluorescence reducer in fluid communication with contaminated magnetic particle carrier fluid. The filter(s) removes particulate matter less than 1 micron in size. The fluorescence reducer removes soluble fluorescent compounds from the carrier fluid causing background fluorescence contamination. A pump circulates the carrier fluid from a reservoir of contaminated fluid, through the system, and back to the reservoir. A cleaning loop runs the carrier fluid through the filter(s) and fluorescence reducer to remove contaminants to levels acceptable for new magnetic particle carrier fluid. A testing loop may be included that bypasses the filter(s) and fluorescence reducer. A valve may be actuated to toggle between the testing loop and cleaning loop for selective cleaning or use of the carrier fluid for MPI testing. The system may be integrated with an MPI station or may be independent and mobile.

A magnetic particle inspection tool is provided including a yoke with an inspection magnet, a first magnetic member, and a second magnetic member. The inspection magnet is configured to magnetize a work piece. The first magnetic member is rotatable relative to the inspection magnet between a first position and a second position, and the inspection magnet is slidable relative to the first magnetic member. The first magnetic member and second magnetic member include a plurality of magnetic sources forming a magnetic surface with a first magnetic pattern and a magnetic surface with a second magnetic pattern. The magnetic surfaces are magnetically attracted when the first magnetic member is in the first position and repelled when in the second position.

A magnetic particle inspection tool is provided including a yoke with an inspection magnet, a first magnetic member, and a second magnetic member. The inspection magnet is configured to magnetize a work piece. The first magnetic member is rotatable relative to the inspection magnet between a first position and a second position, and the inspection magnet is slidable relative to the first magnetic member. The first magnetic member and second magnetic member include a plurality of magnetic sources forming a magnetic surface with a first magnetic pattern and a magnetic surface with a second magnetic pattern. The magnetic surfaces are magnetically attracted when the first magnetic member is in the first position and repelled when in the second position.

Testing apparatus and handles for testing apparatus are disclosed. An example testing apparatus includes: a first housing portion including a first compartment portion and a trigger compartment; a second housing portion including a second compartment portion that is complementary to the first compartment portion, wherein the first compartment portion and the second compartment portion form a yoke compartment when the first housing portion and the second housing portion are attached; a removable seal positioned around a perimeter of at least one of the first compartment portion or the second compartment portion, wherein the removable seal is configured to be compressed between the first housing portion and the second housing portion to seal the yoke compartment; and a trigger cover complementary to the trigger compartment of the first housing portion, wherein the trigger cover and the second housing portion are removably attached to the first housing portion.

A magnetic particle testing mechanism is provided for testing for defects in an axle of a landing gear assembly. The magnetic particle testing mechanism includes a conductor mechanism. The conductor mechanism is configured to apply a magnetic particle substance onto a portion of the axle and generate a magnetic field within or around the portion of the axle. Generating the magnetic field causes a magnetic field distortion associated with a defect in the axle that attracts the magnetic particle substance indicating a location of the defect in the axle.

A magnetic particle testing mechanism is provided for testing for defects in an axle of a landing gear assembly. The magnetic particle testing mechanism includes a conductor mechanism. The conductor mechanism is configured to apply a magnetic particle substance onto a portion of the axle and generate a magnetic field within or around the portion of the axle. Generating the magnetic field causes a magnetic field distortion associated with a defect in the axle that attracts the magnetic particle substance indicating a location of the defect in the axle.

A magnetic particle inspection tool is provided including a yoke with an inspection magnet, a first magnetic member, and a second magnetic member. The inspection magnet is configured to magnetize a work piece. The first magnetic member is rotatable relative to the inspection magnet between a first position and a second position, and the inspection magnet is slidable relative to the first magnetic member. The first magnetic member and second magnetic member include a plurality of magnetic sources forming a magnetic surface with a first magnetic pattern and a magnetic surface with a second magnetic pattern. The magnetic surfaces are magnetically attracted when the first magnetic member is in the first position and repelled when in the second position.

A magnetic particle inspection tool is provided including a yoke with an inspection magnet, a first magnetic member, and a second magnetic member. The inspection magnet is configured to magnetize a work piece. The first magnetic member is rotatable relative to the inspection magnet between a first position and a second position, and the inspection magnet is slidable relative to the first magnetic member. The first magnetic member and second magnetic member include a plurality of magnetic sources forming a magnetic surface with a first magnetic pattern and a magnetic surface with a second magnetic pattern. The magnetic surfaces are magnetically attracted when the first magnetic member is in the first position and repelled when in the second position.