Abstract: There is provided a pipeline inspection device including: a body part contacting a pipeline and accommodating the pipeline; a coupling part coupled to the body part to enclose the pipeline; and a sensor part including a sensor on at least one of one side of the body part and one side of the coupling part which are in contact with the pipeline to inspect an internal state of the pipeline. The pipeline inspection device according to exemplary embodiments is capable of inspecting pipelines without increasing a gap between the pipelines even in a case in which the gap therebetween is relatively narrow, and is capable of readily and rapidly inspecting a large area of pipelines.
Type:
Grant
Filed:
July 17, 2013
Date of Patent:
July 18, 2017
Assignees:
Korea Electric Power Corporation, Korea East-West Power Co., Ltd.
Inventors:
Doo-Song Gil, Yeon-Shik Ahn, Gye-Jo Jung, Sang-Ki Park
Abstract: In general, according to one embodiment, an inspection apparatus includes a disposition; a vibration detector configured to output a signal corresponding to vibration of the inspection object; a determination module configured to determine presence/absence of abnormality of the inspection object and configured to Fourier-transform an output result of the vibration detector at a time when the inspection object is disposed on the disposition section, to create vibration information indicative of vibration power of a characteristic frequency of each of structural elements of the disposition section, and to determine presence/absence of abnormality of the inspection apparatus, based on the vibration information; and a transmission module configured to transmit an output signal of the vibration detector to the determination module.
Abstract: A system is provided including an acoustic interface device, configured for coupling to a transducer and to a specimen, the acoustic interface device comprising a material composition having a shear wave attenuation coefficient ?S of at least about 5 dB/cm when subjected to an acoustic signal at a frequency between about 200 to 500 kHz. The acoustic interface device may be formed of polytetrafluoroethylene (Teflon®), a perfluoroalkoxy alkane (PFA), polycarbonate (Lexan®), or polyether ether ketone (PEEK). Methods of using the acoustic interface device with a transducer for ultrasonic measurement of a specimen are also disclosed.
Abstract: A detection device includes a driving circuit which drives a physical quantity transducer, a detection circuit which detects a desired signal, a power-supply terminal into which a power-supply voltage is input, a regulator circuit which performs a voltage adjustment of stepping down the power-supply voltage from the power-supply terminal, and supplies a regulated power-supply voltage obtained by the voltage adjustment to the driving circuit and the detection circuit as an operating power-supply voltage, and a buffer circuit which is supplied with the power-supply voltage, receives a drive signal from the driving circuit, and outputs an amplified drive signal in which an amplitude of the drive signal increases to the physical quantity transducer.
Abstract: Apparatus is provided featuring a signal processor configured to receive from an array of ultrasonic transponders around a tank, container or flow pipe signaling containing information about acoustic waves of energy penetrating a fluid in the tank, container or flow pipe; and determine using tomography a three-dimensional image of layers of the fluid in the tank, container or flow pipe based at least partly on the signalling received and. The signal processor provides corresponding signal containing information about the three-dimensional image of the layers of the fluid in the tank, container or flow pipe. The array is an obliquely oriented array of ultrasonic transponders arranged on an oblique plane to the axis of the tank or column; or the array is placed normal to the flow around the exterior of the flow pipe.
Abstract: A device for determining properties of a medium, comprising a carrier which can be brought in contact with the medium; at least one transmitter arranged on the carrier for exciting acoustic waves in the carrier; at least one receiver arranged on the carrier for receiving acoustic waves which originate from waves excited in the carrier by means of the transmitter; and first and second material regions arranged on the carrier, wherein the second material region absorbs sound waves with the frequency of the acoustic waves excited in the carrier more strongly than the first material region. The carrier has a first surface with which it is to be brought in con-tact with the medium and a second surface which faces away from the first surface, wherein the transmitter as well as the first and the second material region are arranged on the second surface.
Abstract: An acousto-optic crystal optical waveguide is applicable to an acoustic wave sensor for sensing acoustic wave, wherein the acousto-optic crystal optical waveguide includes an acousto-optic crystal core and an inner cladding layer covering the acousto-optic crystal core. The acoustic wave is able to change the refraction index of the acousto-optical crystal optical waveguide to make a light beam with specific wavelength refracting to outside of the acousto-optic crystal waveguide when a light beam transmits through the acousto-optic crystal optical waveguide. Objective of acoustic wave sensing is achieved by detecting wavelength and intensity variation of the light beam transmits through the acousto-optic crystal optical waveguide.
Abstract: Provided is an inspection device, including: pressurizing means for pressurizing an outer member of a rolling bearing toward an inner member of the rolling bearing, the rolling bearing including the outer member and the inner member rotatable relative to each other through intermediation of balls; rotary drive means for rotating the inner member about an axial center of the inner member under a state in which the outer member is pressurized toward the inner member; detecting means for detecting vibration generated along with the rotation of the inner member so that whether or not the rolling bearing is an accepted product is determined based on values obtained through the detection; and vibration control means to be interposed between the outer member and the pressurizing means, the vibration control means including a holding portion configured to hold the detecting means in a fixed manner.
Abstract: An object information acquiring apparatus that transmits an acoustic wave to an object, and receives and analyzes the reflected acoustic wave to acquire internal information of the object, comprises a probe that transmits and receives the acoustic wave; a holding member disposed between the object and the probe to hold the object; and an air bubble detection unit that detects an air bubble present between the object and the holding member on the basis of an intensity of the acoustic wave received after a first time from the transmission by the probe, the first time being calculated on the basis of a time when the acoustic wave reaches a predetermined distance.
Abstract: A method of measuring acoustic energy impinging upon a cable includes, interrogating at least one optical fiber of the cable with electromagnetic energy, the at least one optical fiber is nonconcentrically surrounded by and strain locked to a sheath of the cable, monitoring electromagnetic energy returned in the at least one optical fiber, and determining acoustic energy impinging on the cable.
Type:
Grant
Filed:
March 18, 2015
Date of Patent:
June 13, 2017
Assignee:
BAKER HUGHES INCORPORATED
Inventors:
Paul F. Wysocki, Ian Mitchell, Matthew Thomas Raum
Abstract: Provided is a photoacoustic apparatus capable of recognizing variation in reception characteristic among a plurality of receiving elements that detect an acoustic wave in the photoacoustic apparatus, with a simple configuration unique to the photoacoustic apparatus. A photoacoustic apparatus includes a detecting unit including a plurality of receiving elements configured to detect an acoustic wave that is generated when an analyte is irradiated with light; a signal processing unit configured to acquire information about the inside of the analyte from a detected signal acquired from the detecting unit; an optical absorber configured to absorb the irradiation light; and a reception characteristic calculation unit configured to calculate reception characteristic information of the plurality of receiving elements on the basis of detected signals when the plurality of receiving elements receive an acoustic wave that is generated from the optical absorber.
Abstract: Provided are devices, systems, and methods for the testing of materials and structures. For example, the devices, systems, and methods are optionally used for the non-destructive testing of a material or structure. Furthermore, the devices, systems, and methods may optionally use a high-amplitude, air-coupled acoustic source for non-destructive testing of materials and structures.
Type:
Grant
Filed:
August 30, 2013
Date of Patent:
June 13, 2017
Assignee:
Board of Regents, The University of Texas System
Inventors:
Jinying Zhu, Michael R. Haberman, Xiaowei Dai
Abstract: A method may involve positioning a fixture over a portion of a tube portion of a gasket, where the gasket includes a first lip portion joined to a second lip portion by a weld of the gasket and the first lip portion joined to the second lip portion defines the tube portion, where the fixture comprises a housing and an injection port; positioning an ultrasonic probe in the housing; filling, by the injection port, coupling fluid between the ultrasonic probe and the tube portion of the gasket; and scanning at least a portion of the weld with the ultrasonic probe, where scanning the at least a portion of the weld may involve transmitting, by the ultrasonic probe, a plurality of ultrasonic waves through the coupling fluid into the tube portion, and translating the fixture in a longitudinal direction along the tube portion of the gasket.
Abstract: An ultrasound probe assembly includes a transducer configured to transmit and receive ultrasound signals in relation to a structure, and a delay line coupled to the transducer. The delay line is configured to change shapes between an uncompressed state and a compressed state. In at least one embodiment, the changing shape of the delay line changes a shape of the ultrasound signals.
Abstract: Methods for ultrasonically imaging a heterogeneous 3D-cell population without physically probing are provided. The method can comprises: pulsing ultrasound waves having a wave frequency of about 10 MHz to about 2 GHz through a lens rod, wherein the lens rod focuses the ultrasound waves onto the cell population via a concave lens-head (e.g., comprising sapphire), and wherein the cell population is positioned on the reflective surface such that the ultrasound waves are reflected back to the lens-head; receiving the reflected waves through the lens head and the lens rod at a signal receiver; scanning the lens-head across multiple points in the x,y plane; and at each point in the x,y plane, moving the lens-head in a z-direction such that a signal is received at multiple intervals in the z-direction for each point in the x,y plane.
Abstract: Provided are a vibration detector and a vibration detecting method, which are power saving, can detect vibration even if the vibration is very weak, and can perform both start-up of the apparatus and collection of data of vibration information by the use of only one sensor. The apparatus includes a vibration detector, a semiconductor switch, a controller and a power supply. The semiconductor switch and the controller are connected to the power supply. The vibration detector detects vibration and consequently generates a vibration voltage. The semiconductor switch includes a voltage divider for generating a bias voltage inside. The semiconductor switch detects a voltage produced by superposing the bias voltage onto the vibration voltage outputted from the vibration detector, and conducts current when the detected voltage is equal to or larger than a certain value. The controller wakes up with the current conducted by the semiconductor switch as a trigger signal.
Abstract: An acoustic line tracing system for tracing a fluid transfer system tubing line includes an acoustic receiver operably connectable to the tubing line and configured to receive the vibratory signal. The acoustic receiver includes a vibration sensor disposed to contact the tubing line and configured for detecting vibration of the surface of the tubing line caused by the vibratory signal, and an indicator producing at least one of an audio and a visual cue when the vibration sensor detects the vibratory signal.
Type:
Grant
Filed:
April 20, 2016
Date of Patent:
May 23, 2017
Assignees:
BAXTER INTERNATIONAL INC., BAXTER HEALTHCARE S.A.
Inventors:
James Scott Slepicka, Thomas Edward Dudar
Abstract: A movement simulator [100] has at least three translational degrees of freedom and has at least three actuator assemblies [106, 108, 110] each of which having a four bar parallelogram/trapezoidal link arrangement. A stiffener [214] is also disclosed.
Type:
Grant
Filed:
January 29, 2013
Date of Patent:
May 16, 2017
Assignee:
Moog BV
Inventors:
Jean-Paul Warmerdam, Jan Hordijk, Hanjo Hoogendoorn
Abstract: The present invention provides an apparatus for measuring the propagation velocity of a sound wave that may easily and accurately measure the propagation velocity of a sound wave in the horizontal and vertical directions of the sample by using the fixing unit preventing the measurement unit from vibrating and the distance measurement unit capable of accurately measuring the distance between the sound wave transmission and reception units, and a method of measuring the propagation velocity of a sound wave by using the apparatus.
Type:
Grant
Filed:
December 2, 2014
Date of Patent:
May 9, 2017
Assignee:
KOREA INSTITUTE OF GEOSCIENCE & MINERAL RESOURCES
Inventors:
Gil Young Kim, Dae Choul Kim, Young Kyo Seo, Gwang Soo Lee