According to one embodiment, a transducer includes first structure sections and second structure sections. The first structure sections are spaced from each other in a first direction. Part of each of the first structure sections is fixed. The each of the first structure sections includes a first membrane part, a first piezoelectric part, a first conductive part, and a first electrode. The second structure sections are spaced from each other in the first direction. Part of each of the second structure sections is fixed. The each of the second structure sections includes a second membrane part, a second piezoelectric part, a second conductive part, and a second electrode. The second structure sections are spaced from the first structure sections in the first direction. Pitch along the first direction of the second structure sections is shorter than pitch along the first direction of the first structure sections.

A moving inspection device inspecting an inspection target while realizing the simplification of the configuration and significant size reduction/weight reduction of the device, a moving inspection method, and a method for manufacturing a steel material. The device includes a moving inspection device body configured to inspect an inspection target for defects while moving over its surface. The moving inspection device body includes: a carriage that moves by at least two wheels that rotate forward and backward over the surface; and at least one inspection sensor on the front end side or the rear end side of the carriage. An inspection region of the inspection target is divided into two divided regions across a straight line, and the carriage is configured to move when the inspection sensor is directed to side edges sides of the divided regions facing the straight line in each of the two divided regions.

A non-contact non-destructive testing method includes spatially and/or temporally controlling a laser excitation light based on a predetermined pattern. The laser excitation light is projected onto a surface of a test object to generate acoustic waves on the test object. The acoustic waves apply stress loading to the test object. The method also includes imaging the test object with and without stress loading using shearography imaging, and analyzing shearography imaging data to determine a presence of a defect in the test object.

The invention is applied to an ultrasound inspection apparatus including an array probe such that wetting is substantially limited to an inspection surface of the work. The ultrasound inspection apparatus includes: a work holder that holds a work with an inspection surface thereof facing downward; an array probe that probes the work with an ultrasonic wave; a water tank in which the array probe is immersed in water; an arm that holds the array probe such that the array probe faces an underside of the inspection surface of the work; X-axial direction scanning means that horizontally scans the work, with a liquid surface coming into contact with the inspection surface of the work due to surface tension of a liquid stored in the water tank; and Y-axial direction scanning means that horizontally scans the array probe.

An ultrasonic device includes: a first and second flaw detection head; a moving mechanism that causes the first flaw detection head and the second flaw detection head to perform scanning; a calibration area in which a calibration standard sample is disposed; a flaw detection area in which an inspection object is disposed; and a controller that performs a first calibration process or a second calibration process, the first calibration process being a process of causing the first flaw detection head to scan the calibration standard sample to perform calibration using the calibration standard sample, the second calibration process being a process of causing the second flaw detection head to scan the calibration standard sample to perform calibration using the calibration standard sample when performing a first flaw detection process of performing ultrasonic flaw detection inspection of the inspection object by the first flaw detection head.

A device according to an embodiment of the present invention for detecting an internal flaw in a steel plate by using a height-adjustable ultrasonic sensor may comprise: a spray nozzle installed a certain distance apart from the bottom of a steel plate, for spraying a medium toward the steel plate and forming a medium column; an ultrasonic sensor installed inside the spray nozzle, for transmitting and receiving ultrasonic waves for detecting flaws in the steel plate through the medium column; a flaw detecting unit for detecting the presence of internal flaws in the steel plate on the basis of the transmitted and received ultrasonic waves; and a driving unit installed inside the spray nozzle, for adjusting the distance between the ultrasonic sensor and the steel plate according to the thickness of the steel plate.

A holder for attaching an acoustic emission sensor to a non-metallic and non-magnetic material has a tubular body with a closed top end and an open bottom end through which the sensor is insertable into the tubular body. The closed top end has a plurality of unitary flexible flaps angularly extending inwardly from an inner surface of the enclosed top end. An inner surface of the tubular body has a plurality of spacers extending radially inward proximate the bottom end of the tubular body. The unitary flexible flaps and the spacers fix the sensor within the tubular body. The tubular body may also have a plurality of capture tabs extending outwardly from an exterior surface thereof proximate the open bottom end that are slidably and removably engageable with an engagement keyway in a retainer bracket that is affixed to a non-metallic and non-magnetic material.

An ultrasonic flaw detector includes: a flaw detection head including a probe that transmits an ultrasonic wave to an inspection object formed by a composite member and receives the ultrasonic wave that has reflected on the inspection object; a moving mechanism, which causes the flaw detection head to perform scanning; and a support mechanism disposed such that the support mechanism comes into contact with a lower surface of the inspection object, the support mechanism supporting the inspection object. The support mechanism is configured to come into contact with the inspection object over a predetermined area such that a waveform of the ultrasonic wave that has reflected on a position where the support mechanism is in contact with the inspection object and that is received by the probe is within a noise level.

An apparatus and a method for ultrasonic detection are provided. The apparatus includes an injection nozzle which is installed below a steel plate being transported and forms a medium column by jet a medium toward the steel plate, an ultrasonic probe which is installed in the injection nozzle and transmits and receives ultrasonic waves for detecting flaws in the steel plate through the medium column, and a medium circulation unit which reclaims the medium which falls from the medium column and circulates the reclaimed medium to the injection nozzle.

An inspection device is provided which comprises a receiving member defining an open cell for receiving a target therein. An optical excitation input is in optical communication with the cell for exciting the target. At least one acoustic pickup is in acoustic communication with the cell for picking up acoustic energy resultant from excitation of the target. A recorder is provided for recording the acoustic energy picked up from the at least one acoustic pickup for facilitating structural analysis of the target.