A wear sole, an ultrasonic inspection apparatus having a wear sole, and methods for using the same are provided. In one embodiment, the ultrasonic inspection apparatus can include a body, a wear sole, and a fluid channel. The body can define a first chamber configured to receive a first volume of ultrasonic couplant and a distal end of an ultrasonic probe. The wear sole can define a second chamber configured to receive a second volume of ultrasonic couplant and the wear sole can be removably coupled to a distal end of the body. The wear sole can also have a membrane extending thereacross for separating the first chamber from the second chamber. The fluid channel can extend through the body and the wear sole can be configured to deliver the second volume of ultrasonic couplant to the second chamber.

A system and method measures the thickness of wear liners coupled to wear substrates of industrial equipment. The system includes at least one ultrasonic transducer wear sensor device coupled intermediate the wear liner and wear substrate and a data acquisition device configured to receive thickness data from the wear sensor device. The ultrasonic transducer wear sensor device is battery powered in one embodiment and passivated in an additional embodiment and powered through an interrogation signal.

Device, system and method for emission and reception of ultrasonic signal to and from a test material, wherein the device comprising one or more wheel assemblies (1) wherein each wheel assembly (1) further comprising: one or more transducers (20) arranged partially or completely embedded in a coupling medium/partial or complete inner ring (52, 21), the wheel assembly is further comprising an orbital outer ring (23), and wherein the coupling medium/partial or complete inner ring (52, 21) is connected to an axle (22) in anon-rotating manner and the one or more transducers (20) are fixedly pointing towards the test material (15), and the interface between the inward facing surface (26) of the orbital outer ring (23) and/or the outward facing surface (25) of the coupling medium/partial or complete inner ring (52, 21) comprises a low friction material having an acoustic impedance in the same order as that of the orbital outer ring (23).

Methods, devices, and systems for detecting one or more discontinuities of a structure may include a laser emitter configured to generate and direct an ultrasonic signal into a structure and a receiver comprising an optical microphone. The optical microphone may comprise an array of optical microphones configured in a complementary manner to the emitter.

A method of ultrasonic inspection includes generating, by a phased array ultrasonic probe, a first ultrasonic beam propagating in a fluid and incident at a first angle to a target surface in response to receipt of first instructions. Ultrasonic echoes from first beam reflection by the target are measured and corresponding ultrasonic measurement signals are output. At least one environmental sensor measures at least one fluid property and outputs corresponding environmental signals. One or more processors determine a current speed of sound within the fluid from the ultrasonic measurement signals and environmental signals. Second instructions including a second angle are generated by the processors, based on the current speed of sound, when the current speed of sound differs from a predetermined speed of sound by more than a speed threshold. The ultrasonic probe generates a second ultrasonic beam at the second angle in response to receipt of the second instructions.

Systems and methods for improved visualization of non-destructive testing (NDT) measurements are provided. A probe can be employed to acquire NDT measurements of a target. Images of the target can also be captured during testing. The captured images can be analyzed to identify selected objects therein (e.g., the target, the probe, etc.) Graphical user interfaces (GUIs) including the NDT measurements can be further generated for viewing in combination with the target. In one aspect, the GUI can be viewed as a hologram within a display of an augmented reality device when viewing the target. In another aspect, the GUI can be projected upon the target. The GUI can be configured to overlay the NDT measurements at the location where the NDT measurements are acquired. This display of the NDT measurements can help an inspector more easily relate the NDT measurements to the target and improve reporting of the NDT measurements.

Systems, devices, and methods are provided for selecting a precise value within a large value range. Data received by an ultrasonic inspection device can include a range of values associated with one or more parameters to be configured for performing ultrasonic inspection of a test object. A control in a user interface of the ultrasonic testing device can be provided and can include a display portion displaying one or more parameters and one or more values within the range of values associated with the one or more parameters. The control can also include an interactive portion configured to receive a plurality of inputs. Based on the inputs, a selected value associated with a first parameter can be determined. The selected value associated with the first parameter can be displayed as a static display within the display portion of the control.

Various systems are provided for an ultrasound imaging system. In one example, a method comprises learning a travel path profile and one or more pressures applied along the travel path profile in response to an external handle force and acquiring an ultrasound image along the travel path profile by applying one or more pressures against an acquisition surface of a patient via a robot without the external handle force.

Example computer systems, computer apparatuses, computer methods, and computer program products are disclosed for testing an ultrasonic gas leak detection device. An example method includes determining a rotary position of a rotary selector of the handheld ultrasonic testing device. The method further includes determining whether the rotary position of the rotary selector corresponds to a first testing mode for testing the ultrasonic gas leak detection device or a second testing mode for testing the ultrasonic gas leak detection device. The method further includes generating a first ultrasonic signal for testing the ultrasonic gas leak detection device in response to determining that the rotary position of the rotary selector corresponds to the first testing mode. The method further includes generating a second ultrasonic signal for testing the ultrasonic gas leak detection device in response to determining that the rotary position of the rotary selector corresponds to the second testing mode.

A field portable diagnostic apparatus uses a rotatable disk in which a microfluidic circuit is defined. The microfluidic circuit includes a centrifugal separation chamber receiving a sample to stratify the sample. A magnetic bead holding chamber is communicated to a mixing chamber, where mass amplifying functionalized magnetic-nanoparticles, held in a buffer solution and contained in the magnetic bead holding reservoir communicated to mixing chamber, are mixed with the separated fluid delivered to mixing chamber from the separation chamber. The functionalized magnetic nanoparticles conjugate with a target analyte in the sample. A magnet in proximity to a SAW chamber including a SAW detector draws the functionalized magnetic nanoparticles toward antibodies immobilized on the SAW sensor surface A wash reservoir is communicated to the SAW sensor chamber, and a cleanup/waste reservoir is communicated to the SAW chamber for receive fluid after it has passed through the SAW chamber.