A system for assessment of a battery cell comprises a testing platform, a conveying system, one or more ultrasound sources, and one or more ultrasound sources, and a control unit. The conveying system can move the battery cell to the testing platform for assessment and from the testing platform after the assessment. The control unit can control the one or more ultrasound sources and the one or more ultrasound sensors to perform the assessment. The assessment can comprise determining a state of the battery cell based on the one or more signals generated by the one or more ultrasound sensors. The control unit can control the conveying system to direct the battery cell from the testing platform responsive to the assessment.

An ultrasonic testing probe operable to perform an ultrasonic inspection on a workpiece, the workpiece having an interior region. The testing probe comprises a support; an ultrasonic testing element that is structured to generate an ultrasonic output that is directed toward the workpiece and to receive an ultrasonic input from the workpiece that is responsive to the ultrasonic output, the ultrasonic testing element being movably situated on the support; a motor apparatus structured to be electrically connected with a control apparatus, the motor apparatus comprising a motor that is connected with the ultrasonic testing element and is structured to rotate the ultrasonic testing element with respect to the support; and a bladder that is structured to be movable between an initial state and an expanded state, the expanded bladder structured to be engaged with the workpiece within the interior region and to center the support in the interior region.

An inspection probe and system for inspecting a welded or brazed joint includes a housing having an internal cavity and opposed tapered standoffs disposed at a distal end portion of the housing. Distal ends of the opposed tapered standoffs define pivot surfaces, and the opposed tapered standoffs are spaced apart to define a secondary enclosure. A plurality of transducer elements are disposed within the internal cavity of the housing and a primary coupling medium made of a flexible, semi-solid material is secured between the opposed tapered standoffs. A signal processing module is in communication with a data acquisition unit, which is in communication with the transducer elements. The inspection probe is rotated across the joint, data from the transducer elements is communicated to the signal processing module, and reconstructed and corrected images obtained at different angles from the transducer elements are stitched to generate an inspection image.

Provided is an acoustic coupler for ultrasound imaging that can detect a posture of an ultrasound probe from an image. An acoustic coupler includes: a first layer in contact with an ultrasound probe of an ultrasound imaging device; a second layer in contact with an imaging target; and an intermediate layer made of a material having a high elastic modulus between the first layer and the second layer. The intermediate layer includes a plurality of markers made of a material that reflects an ultrasound wave, at different positions in an ultrasound wave propagation direction, for example, near a boundary between two adjacent layers. The ultrasound imaging device detects the posture of the ultrasound probe based on images of the markers included in an ultrasound image.

Disclosed herein is a method for depth-profiling of samples including a target region including a lateral structural feature. The method includes projecting an optical pump pulse on a semiconductor device comprising a target region, such as to produce an acoustic pulse which propagates within the target region of the semiconductor device, wherein a wavelength of the pump pulse is at least two times greater than a lateral extent of a lateral structural feature of the semiconductor device along at least one lateral direction, projecting an optical probe pulse on the semiconductor device, such that the probe pulse undergoes Brillouin scattering off the acoustic pulse within the target region, detecting a scattered component of the probe pulse to obtain a measured signal, and analyzing the measured signal to obtain a depth-dependence of at least one parameter characterizing the lateral structural feature.

A scanning device is provided. The scanning device includes a frame having a first portion and a second portion pivotably coupled to the first frame portion. The scanning device also includes a couplant source disposed in the first frame portion along with a couplant assembly. The couplant assembly includes a first couplant line disposed completely within the first frame portion and the second frame portion. The couplant assembly also includes a second couplant line extending from the first couplant line and out of the second frame portion at a first end of the second couplant line. The couplant assembly has a couplant line branch extending from the second couplant line where a sensor assembly of the ultrasound scanning device couples with the couplant line branch at an end opposite the second end of the second couplant line.

A non-destructive testing calibration system includes a first multi-axis robotic device having a first end effector, a second multi-axis robotic device having a second end effector. A calibration assembly includes an emitter arranged on the first end effector and a receiver arranged on the second end effector, where the emitter and the receiver exchange a calibration signal between the first robotic device and the second robotic device. A data processor and a memory storing instructions, which when executed causes the data processor to perform operations comprising: performing a calibration scan, where the calibration scan includes a plurality of measurement points along a scan path of the emitter and the receiver; measuring the deviation between the emitter and the receiver at each measurement point along the scan path; and determining a corrected scan path based on the deviation between the emitter and receiver at each measurement point during the calibration scan.

A non-destructive testing calibration system includes a first multi-axis robotic device having a first end effector, a second multi-axis robotic device having a second end effector. A calibration assembly includes an emitter arranged on the first end effector and a receiver arranged on the second end effector, where the emitter and the receiver exchange a calibration signal between the first robotic device and the second robotic device. A data processor and a memory storing instructions, which when executed causes the data processor to perform operations comprising: performing a calibration scan, where the calibration scan includes a plurality of measurement points along a scan path of the emitter and the receiver; measuring the deviation between the emitter and the receiver at each measurement point along the scan path; and determining a corrected scan path based on the deviation between the emitter and receiver at each measurement point during the calibration scan.

A device for examining the interior of a pipe using multi-element ultrasound technology, finding application in the detection of defects in the wall of a tubular pipe or the verification of the characteristics of the wall of a tubular pipe is disclosed. The device is designed to be placed inside a fluid transport pipe and to move under the action of the transported fluid, to detect defects in, or check characteristics of, the wall of the pipe. The device has a circumference and comprises a plurality of ultrasonic sensors distributed over its circumference and each formed by a plurality of transmitters and a plurality of reception antennas. The device also includes an electronic controller configured to control each sensor and to receive and record the information measured by the sensors.

An acoustic inspection system can be used to generate a surface profile of a component under inspection, and then can be used to perform the inspection on the component. The acoustic inspection system can obtain acoustic imaging data, e.g., FMC data, of the component. Then, the acoustic inspection system can apply a previously trained machine learning model to an encoded acoustic image, such as a TFM image, to generate a representation of the profile of one or more surfaces of the component. In this manner, no additional equipment is needed, which is more convenient and efficient than implementations that utilize additional components that are external to the acoustic inspection system.