Detection, identification, and monitoring of various composite-damage types such as impact damage, delaminations, etc. using angle-beam coupled guided waves and methods and systems that permit excitation with angle-beam techniques of certain composite-material guided-wave modes that cannot be excited in isotropic metals with angle-beam methods.

Methods and systems for subsurface imaging of nanostructures buried inside a plate shaped substrate are provided. An ultrasonic generator at a side face of the substrate is used to couple ultrasound waves (W) into an interior of the substrate. The interior has or forms a waveguide for propagating the ultrasound waves (W) in a direction (X) along a length of the substrate transverse to the side face. The nanostructures are imaged using an AFM tip to measure an effect (E) at the top surface caused by direct or indirect interaction of the ultrasound waves (W) with the buried nanostructures.

A transmission probe for transmitting guided waves propagating in the longitudinal direction of a long member and a reception probe for receiving guided waves derived from the guided waves reflected from a predetermined portion of the long member are set on the long member. The guided waves received by the reception probe include a guided wave serving as a second signal that is noise of a desired first signal. The guided wave serving as the second signal having nodes in a circumferential direction distribution of displacement in a specific direction in the circumferential surface of the long member, and the guided waves transmitted by the transmission probe are formed such that the displacement of the guided wave serving as the second signal in the specific direction becomes zero at a specific circumferential surface position of the long member. A probe setting method comprising the steps of: setting the transmission probe for transmitting the guided waves on the circumferential surface of the long member; and setting the reception probe at a position at which the displacement of the guided wave serving as the second signal in the specific direction becomes zero on the circumferential surface of the long member.

A system includes a magnetostrictive strip configured to be wrapped at least partially around an outer surface of a structure. A plurality of coil circuits are disposed on at least one flexible PCB that is configured to be disposed adjacent to the magnetostrictive strip. Each coil circuit is individually controllable by a plurality of channels to at least one of excite or detect guided waves in the structure. A plurality of magnets are configured to induce a magnetic field in the magnetostrictive strip. A connector is configured electrically connect at least one of the plurality of coil circuits and at least one the plurality of channels. A body constructed from a flexible material is sized and configured to at least partially encapsulate at least one other component of the system.

A method for monitoring the structural health of a structure that supports guided propagation modes of elastic waves, includes the following steps: a) acquiring an ambient noise propagating through the structure by means of at least one pair of non-collocated elastic-wave sensors; b) estimating a function representative of an impulse response of the structure for elastic propagation between the constituent sensors of said pair; c) extracting at least one dispersion curve of the elastic propagation through the structure by time-frequency analysis of this function representative of an impulse response; and d) estimating at least one parameter indicative of a mechanical property of a constituent material of the structure from the dispersion curve obtained in step c). A system for implementing such a method is also provided.

The present invention discloses an integrated thermocouple waveguide sensor system comprise one or more of compatible wave propagation mediums joined at one junction with at least one ultrasonic energy transducer on at least one open end of one or more wave guides and a method using the integrated thermocouple waveguide sensor system with arrangement of at least one waveguide thermocouple for integrated measurement of multiple and simultaneous physical properties of the waveguide material itself and that of the surrounding media using the Seebeck phenomena and the ultrasonic guided wave phenomena. The surrounding media properties and waveguide material properties are measured based on the ultrasonic waveguide parameters and the temperature is measured by the thermocouple.

Operating parameters are selected for inspecting a structure. Selecting the operating parameters includes exciting broadband ultrasonic guided waves in a multilayered structure, acquiring data corresponding to the sensed broadband ultrasonic guided waves in the multilayered structure, selecting one or more narrow frequency bands based on the acquired data, and inspecting the multilayered structure using ultrasonic guided waves in the one or more narrow frequency bands. In some examples, the data is acquired by an inspection tool capable of sensing the broadband ultrasonic guided waves in the multilayered structure.

An ultrasonic inspection method that includes arranging an ultrasonic transmission element and an ultrasonic reception element symmetrically in relation to a straight line in a diameter direction orthogonal to the cylinder axis of a cylindrical inspection object, the inspection object being interposed between the ultrasonic transmission element and the ultrasonic reception element; transmitting ultrasonic waves from the ultrasonic transmission element at a plurality of positions in the diameter direction; receiving by the ultrasonic reception element the ultrasonic waves transmitted from the ultrasonic transmission element and transmitted through the inspection object by propagating through the inside of the inspection object; and inspecting the inspection object on the basis of a reception signal of the ultrasonic waves received by the ultrasonic reception element.

A system comprising a motorized scanner, a magnetostrictive EMAT sensor, and a mechanism to pressure-couple the sensor against the structure that is going to be ultrasonically inspected. The magnetostrictive EMAT sensor includes a magnet or magnets to provide a biasing field, an EMAT RF coil or coils to generate the RF field, a magnetostrictive strip under the coil or coils where the ultrasound is generated. Different magnet and coil configurations can be used to generate guided waves, such as shear horizontal and lamb waves, or bulk waves at different angles. The motorized scanner moves the sensor on the structure and stops at the desired inspection locations based on position readings. Once in position, a built-in device applies downward pressure on the sensor to pressure couple the magnetostrictive strip against the structure so the ultrasound can propagate within this structure and ultrasonic readings can be taken.

Provided is a sensor and method for weld defect detection. The sensor includes several piezoelectric elements which form a matrix arranged on a flexible substrate. Each piezoelectric element is covered with a damping block and surrounded by sound absorbing material, within a flexible protective film. The sensor is simple, highly adaptable and high detection efficiency, which is especially suitable for the quick in-service inspection of long distance welds in large equipment, it has high degree of automation.