Disclosed is an ultrasound array comprising a plurality of ultrasound transducer elements (20) on a carrier (10), said carrier further carrying an actuator arrangement (30, 30) of a material having an adjustable shape in response to an electromagnetic stimulus, e.g. an electro active polymer or optically responsive polymer, wherein the material is arranged to change the orientation of said ultrasound transducer elements in response to said stimulus. This facilitates configurable beam shaping and/or body contour matching with the ultrasound array. An ultrasound system (100) comprising such an ultrasound array is also disclosed.

Transmit-Receive Longitudinal (TRL) probes can be used for the inspection of noisy material, such as austenitic materials. By using various techniques, an inspection area is not constrained by a wedge design of an ultrasonic probe and the benefits of using a linear probe array (rather than a matrix) are maintained. Volumetric or TFM-like imaging on austenitic materials using a linear transmit array and a linear receive array that are out of plane with one another (a TRL configuration) and not in the main imaging place can simplify the inspection and analysis of such materials. For each scan position, an ultrasound probe can acquire acoustic imaging data. Then, a processor can then combine acquisitions from adjacent scan positions to create an imaging result using synthetic aperture focusing technique (SAFT) principles to recreate a focalization in a passive axis of the probe.

A fluid impermeable transducer includes an assembly of a transducer head and a casing, and an actuator disposed in the casing rearward of the back of the transducer head and operable to transmit acoustic energy through the transducer head. The transducer head and casing define a working portion of the transducer that is fluid impermeable.

The present disclosure provides a system and method for real-time visualization of a material during ultrasonic non-destructive testing. The system includes a graphical user interface (GUI) capable of showing a three-dimensional (3-D) image of a composite laminate constructed of a series of two-dimensional (2-D) cross sections. The GUI is capable of displaying the 3-D image as each additional 2-D cross section is scanned by an ultrasonic testing apparatus in real time or near real time, including probable defect regions that contain a flaw such as a hole, crack, wrinkle, or foreign object within the composite. Furthermore, in one embodiment, the system includes an artificial intelligence capable of highlighting defect areas within the 3-D image in real time or near real time and providing data regarding each defect area, such as the depth, size, and/or type of each defect.

A method for nondestructively testing a part comprising an elongate microstructure is disclosed. The method comprises: moving a linear transducer to a plurality of positions located facing a surface of the part, the linear transducer comprising a plurality of transducer elements that are aligned along a main direction; emitting a plurality of elementary ultrasonic beams, each of the plurality of elementary ultrasonic beams being emitted by each of the plurality of transducer elements in the direction of the surface; measuring a plurality of echo signals and a plurality of structural noises, each of the plurality of echo signals and each of the plurality of structural noises being measured by each of the plurality of transducer elements, each of the echo signals resulting from the backscatter of the elementary ultrasonic beams by a defect under the surface of the part, and each of the structural noises resulting from the backscatter of the elementary ultrasonic beams by the elongate microstructure; and determining a direction of elongation of the elongate microstructure when an amplitude of one among the plurality of measured structural noises is minimal in the plurality of positions. Furthermore, a non-destructive testing system for implementing the testing method is disclosed.

A fluid impermeable transducer includes an assembly of a transducer head and a casing, and an actuator disposed in the casing rearward of the back of the transducer head and operable to transmit acoustic energy through the transducer head. The transducer head and casing define a working portion of the transducer that is fluid impermeable.

An ultrasound probe including a matching element, a backing layer, a piezoelectric element and a driver is provided. The piezoelectric element is disposed between the matching element and the backing layer. The driver generates a coding wave inputted to the piezoelectric element, such that the piezoelectric element outputs a focusing sonic wave field along a short axis.

A manufacturing method is used for an outer joint member of a constant velocity universal joint. The outer joint member includes a cup section having track grooves formed in its inner periphery, which are engageable with torque transmitting elements, and a shaft section formed at a bottom portion of the cup section. The manufacturing method includes welding the cup and shaft members by irradiating a beam to joining end portions of the cup and shaft members, causing an outer surface including the welded portion to be formed into a flat smooth surface by removal processing, irradiating ultrasonic waves to the flat smooth surface with one probe at an incident angle which prevents total reflection in a circumferential angle beam flaw detection method, and setting a focal point of the ultrasonic waves to positions from a surface to an inside of the welded portion, to thereby perform inspection.

An ultrasonic flaw detecting apparatus comprises an array prove, an element-group defining circuit, a calculator, a signal receiver and a generator. The array probe comprises a plurality of piezoelectric elements, each of the plurality of piezoelectric elements being configured to transmit and receive an ultrasonic wave to and from an inspection object. The element-group defining circuit is configured to select, as an element group, plural consecutive piezoelectric elements from the plurality of piezoelectric elements, set a reference position of the element group based on array arrangement information of the plurality of piezoelectric elements in the element group and based on a weighting value of each of the plurality of piezoelectric elements in the element group, and calculate a propagation path of an ultrasonic beam from the element group based on the reference position and a predetermined refraction angle. The calculator is configured to calculate a delay time of each of the plurality of piezoelectric elements in the element group in such a manner that the ultrasonic beam is configured to propagate along the propagation path. The signal receiver is configured to receive respective ultrasonic waves received with the plurality of piezoelectric elements as detection signals. The generator is configured to generate at least one composite signal for the ultrasonic beam having the propagation path based on the detection signal and the delay time.

An imaging device includes a transducer that includes an array of piezoelectric elements formed on a substrate. Each piezoelectric element includes at least one membrane suspended from the substrate, at least one bottom electrode disposed on the membrane, at least one piezoelectric layer disposed on the bottom electrode, and at least one top electrode disposed on the at least one piezoelectric layer. Adjacent piezoelectric elements are configured to be isolated acoustically from each other. The device is utilized to measure flow or flow along with imaging anatomy.