PA Probe Catalog.en

March 25, 2018 | Author: dedicateminds | Category: Bandwidth (Signal Processing), Nondestructive Testing, Microscopy, Ultrasound, Medical Ultrasound
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PHASED ARRAY INSPECTIONSPhased Array Probes and Wedges • • • • • Matched to Rexolite Probes Matched to Water Probes Integrated Wedge Curved Array Probes Wedges 920-165D-EN The Company Olympus Corporation is an international company operating in industrial, medical, and consumer markets, specializing in optics, electronics, and precision engineering. Olympus instruments contribute to the quality of products and add to the safety of infrastructure and facilities. Olympus is a world-leading manufacturer of innovative nondestructive testing and measurement instruments that are used in industrial and research applications ranging from aerospace, power generation, petrochemical, civil infrastructure, and automotive to consumer products. Leading-edge testing technologies include ultrasound, ultrasound phased array, eddy current, eddy current array, microscopy, optical metrology, and X-ray fluorescence. Its products include flaw detectors, thickness gages, industrial NDT systems and scanners, videoscopes, borescopes, high-speed video cameras, microscopes, probes, and various accessories. Olympus NDT is based in Waltham, Massachusetts, USA, and has sales and service centers in all principal industrial locations worldwide. Visit www.olympus-ims.com for applications and sales assistance. UNDERSTAND ING Examples of focal laws The distinguishing feature of phased and delay) of array ultrason individual element ic testing can generate a focused ultrason s in a multielement probe. is the computer-controlled angle, focal distance The excitatio excitation (amplitu ic beam with n of the possibility , and focal spot de interference, of dynamically multiple piezocomposite size through the element modifying beam software. To the desired focal various active transducer generate a parameters such s elements are point hits the as pulsed at slightlybeam in phase by means each element of constructive are time-shifted various transducer element different times. response from s with a comput before being Similarly, the the desired focal summed echo from able time shift. point and attenuat together. The resultin The g sum is an A-scan echoes received by es echoes from that other points in the test piece. emphasizes the Basic Concep ts Types of Probes Angle Beam Illustration of beam focusing Illustration of beam steering With electron ic a group of activescanning, a single focal law is multiplexed angle and along elements; scanning is perform across With sectorial scannin the phased array ed at a constan is equivalent g (also called t scanning), the to a conventional probe length (apertur azimuthal or beam is moved e). This a raster scan ultrasonic transdu specifi through a sweep angular for an angled wedgecorrosion mapping or shear-w cer performing ranges c focal depth, using the same range with differen elements; other for a ave time delays insideis used, the focal laws compen inspection. If sweep sectors may have t focal depths may be the wedge. sate for differen added. The angular different values. t Electronic linea r scanning Scanning Patt erns Delay values (left) principles (right) and depth scanning for array probe focusing a 32-element linear and 60-mm longitud at 15-mm, 30-mm, inal waves. Sectorial scan ning Dynamic depth focusing (DDF) response-on-rec is eption accomp a programmable, real-time gain, and excitatio lished by modifyin array replaces multiple n of each element as a function g the delay, of time. DDF the emitted beam focal laws for the same focal range created with separate stage. In other by “focused beams” words, as the signal returns DDF dynamically changes at the receiving the to the phased increases the array probe. DDF focal distance depth of field significantly and signal-to -noise ratio. Dynamic dept h focusing Integrated Wed ge Angle beam probes are used with removable or integrated wedge a to transmit a refracted shear or longitudinal wave into a test piece. They are designed for a wide range of applicat ions and can be used to vary the refracted beam angle or of the beam, the skew depending on the wedge orientation. The probe face is acoustically matched to the wedge material . Near Wall This variation of an angle beam probe integrates the wedge into the probe housing. The wedge configuration but offers smaller is fixed overall dimensi ons. Electronic linear scanning Sectorial scanning Acquisition without Linear arrays are the most commo the important features of linear nly used phased array probes for arrays is the active The active aperture probe aperture industrial applications. Thus, (A) is the total . one of active probe A = (n – 1) • p length. Apertur +e e length is given by the followin where n = Number g formula: of elements in the PA probe p = Elementary pitch—distance between the two adjacent centers of elements e = Element width— width of a single element (a practica piezocomposite l value is e < g = Gap between λ/2) v λ= adjacent element s f where λ = Wavelen gth v = Material sound velocity f = Frequency Phased Array Probes DDF Acquisition with DDF Phased array probes are made different applicat in a ions. A few types variety of shapes and sizes for are illustrated here: The near wall probe is specifi cally designed to minimize the dead zone at probe ends by reducing the distance between available element the last and the external the housing. This edge of probe type is useful for composite radius and corner inspectio or any applicati ns, on requiring close contact to a wall using a 0° wedge. Immersion Time-Correct ed Gain Distance-amplitude curves (DAC) the time-corre used to create cted gain (TCG) Defect Positio ning In order to cover the whole volume consistency, of the part each attenuation and focal law has to be calibrate with beam spread. d for gain (TCG) calibrati This time-correctedcalibration block on can be performed with a having several (for example identical refl , side-drilled ectors holes) Using a sectoria l scan, the probe at different depths. and forth so is moved back that each beam amplitude of hits each refl ector. The each used to constru signal is recorded (DAC) and ct one TCG curve per focal law. Once the TCG calibration is completed, each a consequence, position inside a reflector will always yield focal law has one individu al TCG the same signal the part and of the beam with an angle amplitude, regardlecurve. As that of ss of its detected at 60 45 degrees will provide the detected it. A defect at 3 mm in depth degrees. same signal amplitu detected de as if it were at 10 mm and Two-dimensiona l arrays have multiple strips of linear arrays to allow electronic focusing and steering in both probe axes. 2-D arrays have the same number of elements in both dimensi ons, whereas 1.5-D identifies probes with any combination of uneven number elements. The s of probes can be used for achieving optimal focusing capabili to cover a defi ty or ned area without probe movement. Two linear or two 1.5-D array probes can be positioned on a roof-ang led wedge with a transmit ting probe. The probe is paired with a receiving equivale nt for optimal perform ance in noisy materials such as austenit ic steel. This configuration is a phased-array equivalent to a dualelement probe in conventional UT and is widely used in the power-g eneration industry. 2-D and 1.5-D Arrays Immersion probes are designed be used with to a water wedge or in an immersion tank when the test part is partially or wholly immersed. The acts as a uniform water couplant and delay line. Immersion probes are longitudinal-wav probes that can e be set shear-wave inspecti up for refracted Immersion probes on under water. are mostly intende for automated d inspections. In order to support the growing NDT community, Olympus has published the “Understanding Phased Array Technology” poster. This poster has been designed by field experts to present phased array inspection technology in a concise and clearly illustrated manner. Get your free poster at www.olympus-ims.com. Dual Arrays For manual inspecti ons, real-time respect to the readings are part geometry essential to quickly and/or probe position the location. reflected signal source with www.olympus -ims.com The leader in phased array technology for more than a decade Copyright © 2006–2009 by Olympus NDT. 920-172A_EN All rights reserved. - Poster_PA_E N_200906.ind d RA, PA, DA, and SA readings allow position the the user defect in real time during an to accurately RA: Reference inspection. point to the indicatio n in gate A PA: Probe front face to the indicatio n in gate A DA: Depth of the indicatio n in gate A SA: Sound-path length to the indication in gate A Phased array training is available professional from companies. Visit www.oly mpus-ims.com Olympus NDT Training Acade my 2 www.olympus-ims.com . . . . . . . . . . . .Table of Contents Introduction to Phased Array Technology . . . . . . . . . . . . . . . . . . . . . . . . . A12. . . . . 23 Training . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 I1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . NW2. . . . . . . . . . . . . . . . . . . . . . . . . 10 PWZ1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . and I4 Immersion Probes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Wedge Offset Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 NW1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Wedges Wedges for Angle Beam Probes . . . . PWZ2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 7 7 8 Phased Array Probes A10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . and Support Testing and Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . and A14 Universal Probes . . . . . . . and A16 Weld Inspection Probes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 A1 and A2 Legacy Probe Specifications and Dimensions . . . . . . I3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 R1. . . . . . . . . . . . . . . . . A11. . . . . . . . . . . . 21 Wedge Options. . . . . . . . . . . . . . . . . . . 22 Testing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . and A15 Small-footprint Probes . . . . . . . . . . . . . . . . . . . . Custom Probes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . and R5 Curved Array Probes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Documentation. . . . . . . . . . . . . . . . . . . . . . . . . . . . and NW3 Near-wall Probes . . . and A5 Deep Penetration Probes . . . . . . . . . . . . . . . . Phased Array Probes Application Matrix . . . . . . . . . . . . . . . . . . . 16 Immersion Corner Wedges for Curved Array Probes . I2. . . . . . . . . 20 Options Probe Options and Spare Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 A3. . . . . . . . . . . . . . . . . . . . . . . R4. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 A00. . . 24 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . PWZ3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SW1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 DGS1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Ordering Information . . . . . . . . . . . . . . . . . . . . . . . A0. . . . . . . . . . A4. . . . . . . and AWS1 Integrated Wedge and Code Compliant Probes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . focal distances. and other complex shapes. various beam angles and focal lengths is used to inspect parts with complex shapes such as turbine discs. focal distance. The excitation of multiple piezocomposite elements generates a focused ultrasonic beam allowing the dynamic modification of beam parameters such as angle. To generate a beam in phase by means of constructive interference. Acquisition unit Phased array unit Probe elements Pulses Trigger Incident wave front Multiple-Angle Inspection with a Single. reactor nozzles. The echoes received by each element are time-shifted before being summed together. and Focal Spot Size To generate a beam.olympus-ims.Introduction to Phased Array Technology The distinguishing feature of phased array ultrasonic testing is the computer-controlled excitation (amplitude and delay) of individual elements in a multielement probe. beams of various angles. θ 4 www. Small. Electronically Controlled. Similarly. The resulting sum is an A-scan that emphasizes the response from the desired focal point and attenuates echoes from the other points in the test piece.com . the various probe elements are pulsed at slightly different times. turbine blade roots. and focal spot sizes can be produced. the various active transducer elements are pulsed at slightly different times. By precisely controlling the delays between the probe elements. and focal spot size through software. A single phased array probe can be made to sequentially produce the various angles and focal points required by the application. Focal Distance. Delay (ns) PA probe Angle steering Incident wave front Emitting Transmitting delays Flaw Inspection of Complex Shapes Reflected wave front Echo signals Receiving Receiving delays and sum Flaw The capacity to produce at will. The echo from the desired focal point hits the various probe elements with a computable time shift. the echo from the desired focal point hits the various transducer elements with a computable time shift. Multielement Probe A conventional UT inspection requires a number of different transducers. The resulting sum is an A-scan emphasizing the response from the desired focal point and attenuating various other echoes from other points in the material. All Olympus phased array systems offer the following capabilities: Software Control of Beam Angle. and under computer control. The signals received at each probe element are time-shifted before being summed together. C-scans. RA: Reference point to the indication in gate A PA: Probe front face to the indication in gate A DA: Depth of the indication in gate A SA: Sound path length to the indication in gate A Top B0 Bottom 45° T1 Top Active group 16 1 128 Scanning direction High-speed linear scan: Olympus phased array systems can also be used to inspect flat surfaces such as steel plates.High-Speed Scans with No Moving Parts While phased arrays imply handling the many signals from multielement probes. The difference is that a multiple-angle inspection can be handled with a single transducer. and SA readings allow the user to accurately position the defect in real time during an inspection. PA. DA. filtered. RA PA DA SA 5 . Multiplexing also allows motionless scanning: a focused beam is created using a few of the many elements of a long phasedarray probe. single-element transducer—often referred to as a “paint brush”—phased array technology offers a much higher sensitivity due to the use of a small focused beam. and D-scans built from the A-scan are also identical to that of a conventional system. Compared to a wide. This signal can be evaluated. Defect Positioning For manual inspections. RA. real-time readings are essential to quickly position the reflected signal source with respect to the part’s geometry and/or probe location. processed. it is important to note that the resulting signal is a standard RF signal (or A-scan) comparable to that of any conventional system with a fixed-angle transducer. More than one scan may be performed with various inspection angles. The beam is then shifted (or multiplexed) to the other elements to perform a high-speed scan of the part with no probe movement along that axis. and imaged just as any A-scan from a conventional UT system. The principle can be applied to flat parts using a linear phased array probe or to tubes and rods using a circular phased array probe. B-scans. This value is given by the following formula: N= D2f 4c where D = element diameter f = frequency c = material velocity • To calculate the near-field value in the active (primary) axis of a phased array probe: D = n’ • p.com .5-D Other types of probes can be designed to suit the needs of your application. Linear arrays are the most commonly used phased array probes for industrial applications. This catalog shows Olympus standard phased array probes. The active aperture (A) is the total active probe length. One of the important features that defines phased array probes is the active probe aperture. which are divided into three types: angle beam probes.olympus-ims. integrated wedge probes. where n’ is number of elements per group in the focal law. Linear 1.Phased Array Probes Phased array probes are made in a variety of shapes and sizes for different applications. • To calculate the near-field value in the passive (secondary) axis of a phased array probe: D = Wpassive.5-D array 2-D array Convex Concave Annular Internal focus Skewing Variable angle Dual linear Dual 1. A few types are illustrated here. which is often called elevation. and immersion probes. Olympus offers a wide variety of probes using piezocomposite technology for all types of inspections. Wpassive n=8 p A 6 g www. Typical array probes have a frequency ranging from 1 MHz to 17 MHz and have between 10 and 128 elements. Aperture length is calculated by the following formula: A = n •p where n = number of elements in the PA probe p = elementary pitch—distance between the centers of two adjacent elements A more precise way of finding the active aperture is calculated by this formula: A = (n – 1) • p + e where e = element width—width of a single piezocomposite element (a practical value is e < λ/2) e The near-field (N) value gives the maximum depth of usable focus for a given array. Curved-in-passive-dimension-(focused) • Probe type (angle beam. integrated wedge.6x10-A1-P-2. matrix) • Cable jacket required • Cable length • Connector style • Housing restrictions and/or size constraints Ordering Information Numbering System Used to Order Standard Phased Array Probes 5L16-9. curve) -.5-OM Frequency Array type Number of elements Active aperture Elevation Cable length Cable type Casing type Probe type Connector type Glossary Used to Order Phased Array Probes (Typical options shown) Frequency 1. Elevation Elevation in mm Example: 10 = 10 mm Cable length Cable length in m 2.5 = 1. pitch.Curved-in-active-dimension -.5 = 3. and elevation Array shape (flat.5 MHz 2. Refer to page 6 for details.5 = 7.5D. 2D) CV (ROC) = convex in azimuth CC (ROC) = concave in azimuth CCEV (ROC) = elevation focused Probe type A = angle beam with external wedge NW = near-wall PWZ = weld inspection angle beam W = angle beam with integrated wedge I = immersion DGS = DGS inspection/Atlas (AVG probe) AWS = AWS inspection Connector type OM = OmniScan® connector HY = Hypertronics connector OL = OmniScan Connector with conventional UT channel on element 1 (LEMO 00 connector) ROC: radius of curvature (mm) 7 .Custom Probes Olympus can manufacture custom phased array probes to suit specific applications and geometries. To develop your custom probe.5 = 2.5 MHz 10 = 10 MHz Number of elements Example: 16 = 16 elements Casing type Casing type for a given probe type Cable type P = PVC outer M = metal armor outer Active Aperture Active aperture in mm.25 = 2.5 MHz 5 = 5 MHz 7. immersions.25 MHz 3. we will need to know: • • • • • Application Comparable UT single element transducer Frequency Number of elements.5 m 5 = 5 m 10 = 10 m Array type L = linear A = annular M = matrix probe (1. com .olympus-ims. 8 www.Phased Array Probes Application Matrix Deep Penetration General Purpose Small Footprint Composite Immersion Corrosion Probe Model Weld Typical Application Use Scan Type Additional information Manual A00 A0 A1 A2 A3 A4 A5 A10 A11 Automated Sectorial Sectorial Developed for scribe mark applications Small access. reduced footprint A10 recommended for weld applications A12 recommended for weld applications ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ ✓ Sectorial Sectorial and Linear Sectorial Sectorial Sectorial Sectorial Sectorial Developed for OmniScan 32:128 shear wave and L-wave manual S-scan crack sizing applications Primary probe for carbon steel weld inspection for thickness up to 50 mm (16:128) and 70 mm (32:128) A12 Sectorial and Linear Sectorial and Linear Sectorial Linear Linear Linear Sectorial and Linear Sectorial Sectorial Sectorial and Linear Sectorial and Linear Sectorial and Linear A14 AWS NW1 NW2 NW3 PWZ1 PWZ3 DGS1 I1 I2 I3 I4 AWS weld inspection Designed for near-wall and close access applications Primary probe for carbon steel weld inspection for thickness over 50 mm (16:128) DGS applications HydroFORM corrosion mapping solution This table is only a general application guideline. Please consult your Olympus sales representative prior to ordering. and A12 Probes • Manual or automated inspection of 6. and machined and structural components for cracks and welding defects A10.5L60-A14 Item Number U8330595 U8330251 U8330274 U8330593 U8330785 U8330804 Frequency (MHz) 5.91) 23 (0.0 Elevation (mm) 10. tubes.5 in.60 1.98) 45 (1. A11.77) 68 (2.5 m (8. A11. • Wave layers with acoustic adaptation to Rexolite • Captive anchoring screws are provided with the probe.68) W 16 (0.0 5.91) 23 (0.0 7. pipes.9 19. A11 casing A12 casing L H W A14 casing Probe Specifications and Dimensions Part Number 5L16-A10 10L32-A10 5L32-A11 5L64-A12 5L60-A14 7.60 0.A10.0 60.2 38.2 ft) cable or can be specially fitted with other connectors and cable lengths. • A wide selection of wedges is available to suit any angle beam application.79) 20 (0.0 7.79) 20 (0.0 1.0 10.79) 20 (0.0 10.91) 23 (0.91) 23 (0.63) 16 (0.68) 68 (2.0 5. and A14 Universal Probes 10L32-A10 5L64-A12 5L60-A14 Advantages • Probes are designed to have a low-profile probe/wedge combination for easier access in restricted areas.25 in.79) 20 (0. to 1.4 60.6 9.31 0. 9 .91) H 20 (0.79) These probes come standard with an OmniScan® connector and a 2.63) 23 (0.91) 25 (0.79) 20 (0.5 Number of Elements 16 32 32 64 60 60 Pitch (mm) 0.0 10.0 Active Aperture (mm) 9. forgings.60 0.0 5.0 10. A12.35 mm to 38 mm (0.) L 23 (0.) thick welds • Detection of flaws and sizing • Inspections of castings.0 External Dimensions mm (in. H H W L L W Typical Applications A10.0 10. 94) These probes come standard with an OmniScan® connector and a 2.) L 36 (1. and A5 Probes Deep penetration applications • Thick plates and welds • Forging • Noisy or granular material H H L W A5 casing H W A3 casing L W A4 casing L Probe Specifications and Dimensions Part Number 3.69) 43 (1.42) 57 (2. and A5 Deep Penetration Probes A3 A4 A5 Advantages • Wave layers with acoustic adaptation to Rexolite • Captive anchoring screws are provided with the probe.14) W 36 (1. Typical Applications A3.81) 43 (1. A4.0 24.25L16-A4 2.42) 36 (1.80 2.0 24.2 Elevation (mm) 16.18) 30 (1.42) 46 (1.5 2.5L16-A4 2.8 32.25 5.25 2.0 19. • A wide selection of wedges is available to suit any angle beam application.14) 29 (1.2 ft) cable or can be specially fitted with other connectors and cable lengths.A3. 10 www.60 Active Aperture (mm) 25.0 Number of Elements 16 16 16 16 32 32 Pitch (mm) 1.81) 46 (1.00 0.24) 57 (2.com .20 2.0 External dimensions mm (in.5 5.18) 24 (0.98) 25 (0.0 26.0 20.0 1.0 20.75 0.42) 36 (1.5 m (8.2 44.6 19.5L16-A3 5L16-A3 1.98) 30 (1.69) H 25 (0.25L32-A5 5L32-A5 Item Number U8330094 U8330092 U8330098 U8330692 U8330141 U8330139 Frequency (MHz) 3.0 12. A4.olympus-ims.24) 29 (1.60 1.94) 24 (0. 18) 30 (1.18) 30 (1.0 60.5L60-PWZ1* 5L48-PWZ2 5L32-PWZ3 7.0 18. * Designed for PipeWIZARD system.02) 26 (1.0 7.5 5. this probe comes with a CE Hypertronics connector and a 0.0 10.14) H 30 (1.0 1. In addition.0 Elevation (mm) 10. These cylindrically focused probes significantly reduces oversizing and excessive repairs.0 60. this probe comes with a CE Hypertronics connector and a 0.0 10.5LCCEV100-60-A16 Laterally Focused Arrays (CCEV) Advantages • Low-profile housing • Front-exit cable to avoid interference with the scanner probe holder • Fits special PipeWIZARD® wedges designed for automated inspections of girth welds (sophisticated irrigation channels.0 18.0 10.75 m (2.0 60.0 1.18) 30 (1. Typical Applications • Automated inspection of girth welds with PipeWIZARD systems • Manual or automated inspection of thick welds • Detection of flaws and sizing • Inspection of castings.0 Active Aperture (mm) 60. PWZ2.02) 26 (1.68) 68 (2.14) 29 (1.68) 68 (2.5 Number of Elements 60 60 60 48 32 32 32 60 60 Pitch (mm) 1.5 ft) cable.02) 26 (1. PWZ3.0 7.02) 26 (1.18) 30 (1.68) 68 (2. ** Designed for PipeWIZARD system.0 7.0 1.57) 68 (2.6 m (2 ft) cable.18) These probes come standard with an OmniScan® connector and a 2.0 32.0 1. tubes.5L60-PWZ1 7. forgings.) L 68 (2.5L60-PWZ1 7.57) 40 (1. pipes.0 10. focusing the beam in the lateral direction.0 1. Their capacity to discriminate small indications is a major advantage when sizing the length of an intermittent defect using interaction rules.0 32.0 32.2 ft) cable or can be specially fitted with other connectors and cable lengths. and A16 Weld Inspection Probes 7.0 PWZ1 and A16 casing External Dimensions mm (in.18) 30 (1.0 10.0 5.18) 30 (1.0 48.5L32-PWZ3 10L32-PWZ3 7.68) 56 (2.0 60.02) 29 (1.18) 30 (1. 11 . and machined and structural components for cracks and welding defects H L W Probe Specifications and Dimensions Part Number 5L60-PWZ1 7.PWZ1.20) 40 (1.0 1.02) 26 (1. locking carbide wear pins) • Can be ordered with CE-certified Hypertronics connector • Suitable for manual and automated inspections • Available laterally focused probes improve defect length sizing (7.5 7.5 m (8.0 10.68) W 26 (1.5 7.0 1.02) 26 (1.5 10.0 1.57) 40 (1.18) 30 (1. beam energy is better maintained in small pipe/thin wall applications.5CCEV100-60-A16 7. An integrated lens permits the use of standard wedges.5CCEV100-60-A16** Item Number U8330164 U8330144 U8330086 U8330964 U8330770 U8330209 U8330221 U8330958 U8330796 Frequency (MHz) 5.5CCEV100-60-A16) These new probes for girth weld inspection used with the PipeWIZARD system or COBRA scanner have curved elements in the passive plane. 38) Near-Wall Probes 3.83) 21 (0.0 24.39) 22 (0.0 66 (2.18) 30 (1. NW2.0 6.0 6.83) 25 (0.98) 25 (0.60 0.91) 23 (0.0 NW1 casing Elevation (mm) External Dimensions mm (in.0 6.75) 19 (0.olympus-ims.5CCEV35-A15 U8330145 U8330080 U8330075 U8330110 U8330111 U8330826 10.0 64 64 24 24 128 128 1. H H W L W L Advantages of Near-wall Probes • Shortened dead zone at both ends (1. and A15 Small-footprint Probes NW1.0 64.0 8 (0.51) 13 (0.87) 23 (0.75) 19 (0. and porosity) A00 casing Dimensions are without the strain relief. A0 casing H L W Probe Specifications and Dimensions Part Number Item Number Frequency (MHz) Number of Elements Pitch (mm) Active Aperture (mm) 5.0 10.38) 35 (1.0 5.0 7. A0.18) 35 (1.0 24.98) 30 (1.51) 13 (0.02) 8 (0.50 5.0 1.0 128.5L64-NW1 5L64-NW1 3.39) 10 (0.5CCEV35-A15 10L16-A00 10L16-A00 with SA00-N60S wedge 5L10-A0-TOP 5L64-NW1 Advantages of Small-footprint Probes • Access to confined areas (A00 probe has an 8 × 8 mm footprint) • Cable connector can come out from either the side or the top (A0 only).0 1.0 7.7 (0.0 10.0 7. disbonding.0 5.5 16 10 10 10 10 16 0.60 0.0 6.0 6.31) 10 (0.51) 13 (0.0 1.39) 10 (0. • Special-design small-footprint wedge • 10L16-A00 is used for aerospace scribe-mark applications.60 0.51) 26 (1.5 5.0 1.39) 10 (0.75) 21 (0.5 mm between center of first or last element and housing edge) • Well suited for composite channel inspections • Used for C-scan inspections of composites (delamination.com .60) 66 (2.A00.60) 26 (1.91) 23 (0.31) 13 (0.0 7.2 ft) cable or can be specially fitted with other connectors and cable lengths.5 5.5 m (8.75) 19 (0.12) 19 (0.0 10.0 3.0 7.) L W H Small-Footprint Probes 10L16-A00 5L10-A0-SIDE 5L10-A0-TOP 10L10-A0-SIDE 10L10-A0-TOP 7.0 128. 12 www.31 0.0 6.60 0.0 3.0 7.0 1.91) 23 (0.0 6.0 6.02) 130 (5.0 7.02) 26 (1. and NW3 Near-wall Probes 7.91) 9.91) 23 (0.5 5.5L24-NW2 5L24-NW2 3.5L128-NW3 5L128-NW3 U8330148 U8330134 U8330965 U8330155 U8330695 U8330647 3.0 64.12) 130 (5.38) These probes come standard with an OmniScan® connector and a 2.0 8. • Linear scanning allows coverage of 30 mm to 90 mm in one line.0 7. or other) Composite inspection for delamination.98) These probes come standard with an OmniScan® connector and a 2.38) 35 (1. • Corrosion-resistant stainless steel case • Waterproof guaranteed up to 1 m (3.27) 102 (4.83) 21 (0.0 Active Aperture (mm) 38.28 ft) under water H Typical Applications • • • • Inspection of thin plate or tubing (steel. and I4 Immersion Probes 10L128-I2 7.0 7.0 7.0 96.98) 25 (0.83) 21 (0.27) 83 (3.0 5.0 96.83) 21 (0.50 0.8 64.75) 21 (0.I1. disbonding.75 1.2 ft) cable or can be specially fitted with other connectors and cable lengths.38) 35 (1.38) 35 (1. I2. aluminum.98) 35 (1. with very high accuracy. 13 .38) 25 (0.50 0.4 32.25 5.02) 73 (2.0 External Dimensions mm (in.75) 19 (0.5 m (8. Advantages • Acoustic impedance matches water • Design allows fitting on water wedges for easier coupling on many surfaces and an adjustable water path (when the part to be inspected cannot be immersed in a tank).97) 50 (1.0 76.97) 83 (3. They are longitudinal wave probes that can be set up for refracted shear-wave inspections using a Rexolite wedge.0 10.0 12.60 0.0 10. I3.0 Elevation (mm) 10.5L64-I4 Immersion probes are designed to be used with a water wedge or in an immersion tank when the test part is partially or wholly immersed.) L 50 (1.5 Number of Elements 64 64 128 128 128 128 64 Pitch (mm) 0.25L128-I3 5L128-I3 7.94) H 25 (0.87) W 19 (0.0 10. Inline thickness gaging Automated scanning W L I3 casing H L W I4 casing Probe Specifications and Dimensions Part Number 5L64-I1 10L64-I1 5L128-I2 10L128-I2 2.60 0.0 64.0 10.83) 24 (0.0 7.02) 102 (4.75 0. etc.5L60-I4 Item Number U8330323 U8330012 U8330031 U8330004 U8330351 U8330379 U8330955 Frequency (MHz) 5.0 2. 35 mm to 19 mm (0.0 12.22) 31 (1.75 0.71) Part Number Item Number 2L8-DGS1 4L16-DGS1 2.22) 18 (0.25 5.) thick surfaces (butt joints.0 9.25L16-AWS1 U8330598 U8330597 U8330014 U8330495 U8330496 U8330497 U8330660 2.18) 30 (1.22) 31 (1. and AWS1 Integrated Wedge and Code Compliant Probes 4L16-DGS1 2. tee joints).18) 30 (1.0 4.25L16-AWS1 Advantages • Probe and wedge in the same housing • The lowest-profile probe-and-wedge combination for contact angle beam inspection • Coupling always good between probe and wedge interfaces.0 12.25 8 16 16 16 16 16 16 1.0 0.0 10.59) 15 (0.22) 31 (1.0 2.06) 30 (1.0 Nominal Refracted Beam Angle in Steel 58° SW 58° SW 45° SW 45° LW 45° SW 45° LW N/A Integrated Wedge Elevation (mm) External Dimensions mm (in. to 0.0 10. using 40° to 70° simultaneously • Manual inspection of stress-corrosion cracking • AWS and DGS code compliant applications H L W AWS1 casing W L SW1 and LW1 casings Probe Specifications and Dimensions Number of Elements Frequency (MHz) Pitch (mm) Active Aperture (mm) 8. corner joints.75 0.0 16.0 Yes Yes Yes Yes Yes Yes No These probes come standard with an OmniScan® connector and a 2.2 ft) cable or can be specially fitted with other connectors and cable lengths 14 www.18) 25 (0.67) 15 (0.75 in.59) 15 (0. no need for couplant between the probe and wedge • Very small assembly for easy access in restricted areas • Inspections of 30° to 70° in steel.6 16. SW1.0 9.25 in.6 9.0 12. H W L DGS1 casing H Typical Applications • Manual weld inspection of 6.87) 22 (0.0 8.0 5.59) 15 (0.olympus-ims.0 2.com .59) 38 (1.5 m (8.25 2.60 0.50) H 22 (0.87) 31 (1.0 9.25L16-45SW1 2.25L16-45LW1 5L16-45SW1 5L16-45LW1 2.06) 27 (1.98) W 17 (0.0 12.18) 30 (1.5 0. SW or LW • Easy to handle • Probes with an internal wedge can be specially ordered to fit a specific curvature radius.) L 27 (1.60 1.DGS1.67) 17 (0. 0 5.0 Number of Element 16 16 32 32 64 64 Pitch (mm) 1.5 5.5CC10.5CC50-R5 Advantages • • • • • Acoustic impedance matches water.2 ft) cable or can be specially fitted with other connectors and cable lengths.5CC50-64-R5 5CC50-64-R5 Item Number U8330453 U8330709 U8330629 U8330479 U8330630 U8330636 Casing Type R1 R1 R4 R4 R5 R5 Frequency (MHz) 3. and R5 Curved Array Probes 3.0 6.65 1.5CC25-32-R4 5CC25-32-R4 3.2 10.5 5.2-16-R1 3. OD ID.0 1.28 ft) underwater Compatible with adjustable immersion wedges (shown on page 19) Typical Applications • Inspection of carbon fiber reinforced polymers (CFRP) corners • Composite inspection for delamination R A R casing Probe Specifications and Dimensions Part Number 3. R4.0 6. 15 .0 6.5 5.32 1.R1.0 50.0 3.5CC10.0 Angle (°) (A) 90 90 90 90 121 121 Inspection Type ID ID ID. OD OD OD These probes come standard with an OmniScan® connector and a 2.2-R1 3.32 1.0 6.0 1.5 m (8.0 Radius (mm) (R) 10. High circumferential resolution around the radius Corrosion-resistant stainless steel case Waterproof guaranteed up to 1 m (3.0 25.2 25.0 50.0 3.2-16-R1 5CC10.65 Elevation (mm) 5.5CC25-R4 3. 040 in. The IHC wedge option can be ordered to improve the quality of the inspection: irrigation. 55°. mounting holes for the wedge holder to work with any Olympus scanner.) WP40 = Water pocket (0. 16 www. • Wedges are designed to perform manual or automated scans. and 60° in steel for angle-beam inspections from 30° to 70°. 45°. scanner attachment points.Wedges for Angle Beam Probes SA2-0L SA00-N60S SA10-N55S SA11-N55S SA12-N55S Advantages • • • • Available in standard refracted angles of 0°.005 in.com . and composite wear pins WP5 = Water pocket (0. Lateral electronic scanning replaces the hand-skewing movement (with lateral wedges). • Custom wedges with specific refracted angles can be ordered. Numbering System Used to Order Wedges for Angle Beam probes SA1-N60S-IHC-AOD8 Wedge type Probe mounting Options Wave type Refracted angle in steel Pipe diameter Curvature type Glossary Used to Order Wedges Wedge type SA SAWS SNW SPWZ = = = = wedge wedge wedge wedge for for for for probe type A probe type AWS near-wall probe type NW PipeWIZARD probe type PWZ Wave type Options S = shear wave L = longitudinal wave Probe mounting N = normal L = lateral (90° skew) = = = = 0º 45º 55° 60º Refracted angle in steel 0 45 55 60 IHC = Irrigation. SW or LW Stainless steel screw receptacles provide a firm anchoring of probes to wedges. and carbide wear pins IHC-C = Irrigation. wedge shape and contour can also be customized.olympus-ims. scanner attachment points.) AOD = Axial outside diameter (circumferential scan) COD = Circumferential outside diameter (axial scan) Curvature type Pipe diameter Measured external pipe diameter in in. and carbide pins to increase wear resistance. Wedge Specifications and Dimensions Part Number SA00-0L SA00-N45S SA00-N60S SA0-0L SA0-N45S SA0-N60S SA1-0L SA1-N60S SA1-N60L SA1-L45S SA2-0L SA2-N60L SA2-N55S SA3-0L SA3-N45S SA3-N45L SA3-N60S SA3-N60L SA4-0L SA4-N45S SA4-N45L SA4-N60S SA4-N60L SA5-0L SA5-N45S SA5-N60S SA5-N60L SA10-0L SA10-N55S SA10-N60L SA11-0L SA11-N55S SA11-N60L SA12-0L SA12-N55S SA12-N60L SA14-0L SA14-N55S SA15-N60S SA16-N55S-IHC SAWS1-N60S SAWS1-0L SNW1-0L SNW1-0L-WP5 SNW1-0L-IHC-C SNW2-0L SNW2-0L-WP5 SNW3-0L SNW3-0L-WP5 Item Number U8720002 U8720006 U8720008 U8720004 U8720012 U8720014 U8720016 U8720036 U8720032 U8720024 U8720082 U8720135 U8720096 U8720139 U8720143 U8720141 U8720147 U8720145 U8720149 U8720153 U8720151 U8720157 U8720155 U8720159 U8720163 U8720169 U8720167 U8720544 U8720545 U8720546 U8720553 U8720547 U8720548 U8720549 U8720550 U8720551 U8721079 U8720997 U8721094 U8721469 U8720552 U8720706 U8700264 U8720637 U8700266 U8720924 U8720596 U8721184 U8721219 Probe Type A00 A00 A00 A0 A0 A0 A1 A1 A1 A1 A2 A2 A2 A3 A3 A3 A3 A3 A4 A4 A4 A4 A4 A5 A5 A5 A5 A10 A10 A10 A11 A11 A11 A12 A12 A12 A14 A14 A15 A16 AWS1 AWS1 NW1 NW1 NW1 NW2 NW2 NW3 NW3 Nominal Refracted Beam Angle (in Steel) 0° LW 45° SW 60° SW 0° LW 45° SW 60° SW 0° LW 60° SW 60° LW 45° SW 0° LW 60° LW 55° SW 0° LW 45° SW 45° LW 60° SW 60° LW 0° LW 45° SW 45° LW 60° SW 60° LW 0° LW 45° SW 60° SW 60° LW 0° LW 55° SW 60° LW 0° LW 55° SW 60° LW 0° LW 55° SW 60° LW 0° LW 55° SW 60° LW 55° SW 60° SW 0° LW 0° LW 0° LW 0° LW 0° LW 0° LW 0° LW 0° LW Recommended Sweep (°) −30 to 30 30 to 60 45 to 70 −30 to 30 30 to 60 45 to 70 −30 to 30 30 to 70 45 to 70 −30 to 30 −30 to 30 30 to 70 30 to 70 −30 to 30 30 to 60 30 to 60 45 to 70 45 to 70 −30 to 30 30 to 60 30 to 60 45 to 70 45 to 70 −30 to 30 30 to 60 45 to 70 45 to 70 −30 to 30 30 to 70 30 to 70 −30 to 30 30 to 70 30 to 70 −30 to 30 30 to 70 30 to 70 −30 to 30 30 to 70 35 to 70 30 to 70 45 to 70 -30 to 30 N/A N/A N/A N/A N/A N/A N/A Probe Orientation Normal Normal Normal Normal Normal Normal Normal Normal Normal Lateral Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Wedge Dimensions (mm) L 16 21 21 23 32 32 29 30 28 45 65 79 69 38 55 55 58 53 59 90 88 86 83 38 57 46 39 25 23 26 35 41 43 62 58 61 80 96 18 85 45 38 66 66 66 26 26 130 130 W 12 12 14 12 18 18 30 30 30 35 30 30 30 37 37 37 37 37 47 47 47 47 47 45 47 43 50 23 23 23 23 23 23 23 23 23 23 23 22 31 38 38 32 32 32 32 32 32 32 W* N/A N/A N/A N/A N/A N/A 10 40 40 45 40 40 40 50 50 50 50 50 55 55 55 55 55 55 55 55 55 40 40 40 40 40 40 40 40 40 40 40 N/A 40 N/A N/A 32 32 32 32 32 32 32 H 12 13 13 11 20 21 20 16 21 27 20 50 43 20 30 49 32 40 20 51 85 45 68 20 37 25 41 20 14 30 23 29 53 20 23 53 20 49 12 44 32 40 22 22 22 22 22 22 22 17 . 6 114.0 304.6 114.875) 22 Flat Curvature Range Minimum mm (in.75) (2) (2.5 76.625 8.5 88.5 4 4.1 63.625) (10.2 254.2 82.5) (3) (3.0 152.5 76.75) (12.875) (3.3 168.4 50.) Maximum mm (in.0 323.0 273.75) (1. 3.5) (4) (4.25) (2.4 558.25) (3.625 10.4 555.0 304. SA5.5 5 6 7 8 10 12 16 22 30 Flat 2.5) (4) (4.8 44. SA11.0 152.4 177.4 203. SA4.4 555.8 762.9 101.2 304.olympus-ims.3 219.0 152.8 406.3 168.2 82.9 101.0 (2.75) (12.0 88. SA12.com .3 127.9 101.3 219.5 3 3.5 88.8 406.0 323.9 101.) External Pipe Diameter in.563) (6.8 (2) (2.8 406.9 101. SI2.3 127.6 114. SPWZ3.5) (5.5 76.8 57.5 3 3.563) (6.5) (3) (3.2 88.25) (2.625) (8.2 88.563 6.625) (8.8 (2.5 4 5 6 8 12 16 60.6 114.2 254.4 177.8 57.8 (3.4 558.3 (1. SA14 up to flat www.8) (2) (2.0 152.8 203.5 76. SPWZ1.5) (4) (4.0 50.6 127. Curvature Range Minimum mm (in.1 63.4 203.5 4 4.375) (2.5) (4) (5) (6) (8) (12) (16) (22) Wedge Type: ST and SPE up to flat Wedge Type: SA10. SA3.7 50.5) (5) (6) (7) (8) (10) (12) (16) (22) (30) (2) (2.3 141.1 63.) 88.5) (3) (3.) 73.375) 50.25) (2.5) (5) (6) (7) (8) (10) (12) (16) (22) (30) up to flat 50.5) (5.7 63.375 2. SI1.5) (4) (5) (6) (8) (12) (16) (22) Maximum mm (in. SA2.25) (2.8 406.6 127.8 60.9 101.25 2.25 3.8 203.0 (2) (2.Part Number SPWZ1-0L SPWZ1-N55S REV-C SPWZ3-0L SPWZ3-N55S SPWZ3-N60L *: Width with IHC wedge option Item Number U8700336 U8700336 U8700361 U8700365 U8721399 Probe Type PWZ1 PWZ1 PWZ3 PWZ3 PWZ3 Nominal Refracted Beam Angle (in Steel) 0° LW 55° SW 0° LW 55° SW 60° LW Recommended Sweep (°) -30 to 30 30 to 70 -30 to 30 30 to 70 45 to 70 Probe Orientation Normal Normal Normal Normal Normal Wedge Dimensions (mm) L 75 87 40 65 64 W 30 30 30 30 30 W* 40 40 40 40 40 H 20 45 20 38 35 H H H L W L W L W SA00-N60S SA0-0L SPWZ1-N55S-IHC Standard Wedge Curvature Values External Pipe Diameter in.625) (10.0 273.25) (3.75 Flat 2 2.8 57.2 304.875 18 45.5) (3) (3.5 5.5) (4) (4.25 2. SI3 2 2.75 12.8 51.3 141.75) Wedge Type: SA1.8 762.3 73. ADJ = adjustable radius Note: Not all angles or radii are available. many angle and radii combinations are not available.55) (0.79) Inspection Type ID ID ID OD/ID 19 .55) (0.) 4 to 14 3 to 14 3 to 13 3 to 20 (0.12 to 0. Please consult your Olympus representative to discuss your specific application.12 to 0.125 Wedge type Inspection type Radius Angle of inspected part Glossary Used to Order Wedges Wedge type SR1 = wedge for curved probe type R1 SR4 = wedge for curved probe type R4 SR5 = wedge for curved probe type R5 Angle of inspected part (°) 81 = 81° 90 = 90° 98 = 98° Custom angles can be ordered. Wedge Specifications and Dimensions Part Number SR1-I81-ADJ SR1-I90-ADJ SR1-I98-ADJ SR4-IE90-ADJ Item Number U8720659 U8720638 U8720660 U8720608 Probe Type R1 R1 R1 R4 Angle of the Inspected Part (º) 81 90 98 90 Radius Range mm (in.16 to 0.Immersion Corner Wedges for Curved Array Probes SR1-I81-ADJ SR4-IE90-ADJ Advantages • Available in specific radius and angle and also with adjustable radius to fit on various components to be inspected • Wedges are designed to perform manual scans.51) (0. • Designed to be used with the Mini-Wheel encoder Numbering System Used to Order Wedges for Curved Array Probes SR1-I90-0. Inspection type I = internal E = external Radius Radius in in.12 to 0. as such. 000 0.00 Sec. Offset mm -27.00 Angle: (deg) 39. 3.000 -30.com .Wedge Offset Parameters Angle Center of first element H Z X XT Y L W A Wedge Specification Sheet is provided with every wedge. Offset: (mm) 5.00 Velocity 2330.000 30. Enter the parameters manually using the values provided on the Wedge Specification Sheet accompanying the wedge.00 Velocity: (m ⁄s) -27.00 Height: (mm) TomoView Wedge Parameters Wedge SA1-N60S-IHC Footprint Wedge angle (deg) Roof angle (deg) Sound velocity (m/s) Height at the middle of the first element (mm) Primary axis offset of the middle of the first element (mm) Secondary axis offset of the middle of the first element (mm) Primary axis position of wedge reference (mm) Secondary axis position of wedge reference (mm) Wedge length (mm) Wedge width (mm) Flat 39.com. Offset: (mm) 0.olympus-ims.300 40.00 5.00 ° Pri.30 Pri. This sheet presents the wedge offset parameters of a phased array probe’s first element for both OmniScan® and TomoView™ software.com Wedge parameters with OmniScan X Y Z Primary offset Secondary offset (0 when probe is centered) Height Wedge parameters with TomoView XT Y Z Primary axis offset of the middle of the first element (mm) Secondary axis offset of the middle of the first element (mm) (measured from the side of the wedge) Height at the middle of the first element (mm) Wedge Speci cation Sheet Wedge: Pr obe: SA1-N60S-IHC 2L16-A1.olympus-ims. Call your local sales representative. 2.300 -20.olympus-ims. boul. 20 www. mm Normal Orientation: 2330.5L16-A1 AND 10L32-A1 OmniScan Wedge Parameters Wedge Parameters Model Wedge Angle Serial Number SA1-N60S-IHC Orientation Normal Sec.000 20.00 Height 5. If the wedge is not already in the database.000 3.00 Close Browse New Edit Manage Save 39.000 Note that if the word “reverse” appears on the header of the Wedge Specification Sheet. Olympus NDT Canada 505.000 2330. Offset 0. It is important to note that the values given are only applicable for the wedge and probe combinations listed. du Parc-Technologique Québec (Québec) G1P4S9 Canada Web site: Tel. Parameters are automatically set once the wedge model is chosen.: 1-418-872-1155 Fax: 1-418-872-5431 www. 4.30 m/s mm How to Find the Wedge Parameters 1. it means that the probe is mounted backwards on the wedge. you may download the latest database update from the Service & Support section of www. Find the appropriate wedge in either the OmniScan or TomoView Wedge Database. replace OM with OL. New removable IHC ring for SA10. and harsh environments • Available for most standard probes and extension cables 2 PA Probe Connector Spare Parts Kit P/N: PAPROBE-SP-KIT01 [U8901867] 3 Spare parts kit consists of: 1. M2. 2. 4 mm screws (2) Spring and nylon insert (2) M3 captive thumbscrews (2) 1 4 5 Wedge Options Basic Designed for manual inspection using gel couplant or water (not fed from an irrigation system). Metal Armor Outer • Offers mechanical protection against cut. M1. wear.6. 4. 8 mm screws (2). scanner yoke attachment points. and SA14 wedges offers great flexibility. 3. holes. 5. and four adjustable carbide wear pins. IHC (irrigation. 6 mm screws (6) Gasket (1) M1. and carbides) Same as Basic but with irrigation. SA12. for the Instrument Connector code of the extension cable part number. 21 . SA11. • To order this option.6.Probe Options and Spare Parts OL OmniScan Connector • Additional conventional UT channel (LEMO 00 connector) directly on the OmniScan Connector of the phased array probe • Allows simultaneous or alternate use of phased array and pulse-echo using a single setup. 60 0.) A1 and A2 Legacy Probe Specifications and Dimensions Part Number 2.67) 17 (0.4 38.38) These probes come standard with an OmniScan connector and a 2.98) 25 (0.09) 53 (2.14) 29 (1.olympus-ims.38) 35 (1.98) 35 (1.98) 25 (0.14) H 25 (0.0 12.005 in. H W L A1 casing H 5L16-A1 5L64-A2 L W A2 casing 22 www.WP The “water pocket” option adds a shallow cavity at the base of the wedge to improve the quality of coupling by restricting the flow of couplant.25L16-A1 5L16-A1 10L32-A1 2.5 m (8.14) 29 (1.75 0.4 Elevation (mm) 12.6 9. 0.0 2.0 7.25 5.0 10.0 External Dimensions mm (in.0 38.0 7.com .9 48.14) 29 (1.14) 29 (1.31 0.113 mm (0.25L64-A2 5L64-A2 10L64-A2 Item Number U8330624 U8330070 U8330633 U8330580 U8330072 U8330658 Frequency (MHz) 2.09) 53 (2.0 9.67) 17 (0.0 ® Number of Elements 16 16 32 64 64 64 Pitch (mm) 0.38) 35 (1.2 ft) cable or can be specially fitted with other connectors and cable lengths.14) 29 (1.0 10.75 0.25 5.0 10.60 0.0 10. WP option offers irrigation and scanner yoke attachment points.60 Active Aperture (mm) 12.) L 17 (0.09) W 29 (1.67) 53 (2. This option is only available for SNW wedges. This value is calculated by using the magnitude of the excitation (test) pulse sent to each element and the peak-to-peak voltage measurement of that element’s pulse-echo return (from the test target).96 79.03 81.2 ft) Omniscan Median Waveform FFT The median waveform FFT graph shows the calculated spectrum for the median waveform (see above) over a range of zero MHz to twice the probe’s nominal frequency. 5-L-64-38. PROBE TEST DATA SHEET Part Number: XAAB-0004 Description: ARRAY.Incorrect usage including. or caused by an external accident such as: .5 18 Time (us) Median Waveform FFT 0 Magnitude (dB) 19 50 1 Elements 64 Bandwidth (%) Amplitude (V) The –6 dB percent bandwidth bar graph displays a calculated percent bandwidth value for each of the probe’s elements. 180 V for 7.51 in) 10.5-OM Serial Number: D0259 Probe Information Summary ___________________________________________________________________________ Frequency : Probe Type : Element Count : 5.5 100 -0.0% (band) > 60% (typical) < 4. Avg = 765 ns 1600 64 Time (ns) 0 1 System : FOCUS Scope Volts per Division : 0.9 355 765 5.Excessive voltage (max.5 346 678 Page 2 of 3 1. Tester Signature __________________________ June 19. and the other half will have a smaller value. the firing of the probe in air (WARNING : This will damage the probe) . Avg = 649 ns 1200 Time (ns) 0 1 Elements 64 Elements 64 Warranty Information _____________________ R/D Tech Ultrasonic Transducers offers a one-year warranty on all the phased-array transducers sold by R/D Tech.4X10-A2-P-2.0 mm (0. This information can be accessed to compare probe properties. State College. R/D Tech Ultrasonic Transducers 60 Decibel Road. This form presents the following information: Olympus NDT Ultrasonic Transducers 60 Decibel Road.5 m (8. but not limited to.8 % 1. The warranty excludes defects and deterioration due to normal wear and tear. An extensive database.39 in) Matching Medium : Rexolite Pitch : 0.5-OM Serial Number: D0259 Test Conditions _________________ 600 -20dB Pulse Width. The average value of all the probe’s elements is displayed at the top of the graph. –30 dB and –40 dB. Pass Pass Pass [ [ [ ] ] ] Probe Conformance Summary ___________________________________________________________________________ Parameter Measurement Specification Conformance ___________________________________________________________________________ Average Center Frequency (MHz) Average -6dB Bandwidth (%) Overall Vp-p Sensitivity (dB) Probe Cable Order Checked and Verified Probe Uncoupled Response Checked and Verified Probe Programmable Parameters Checked and Verified 5. 5-L-64-38.127 V Test Medium : Testing on 2cm Rexolite Block -30dB Pulse Width. These products are guaranteed against all defects in materials and manufacturing. 2006 -6dB Center Freq.Exposition to temperatures out of the range of -20º C to +60º C for storage or 10º C to 40º C for operation . is maintained by Olympus.Unforeseen modifications of the product Page 3 of 3 23 . The average value of all the probe’s elements is displayed at the top of the graph. Any shipping costs are at the expense of the customer. The average value of all the probe’s elements is displayed at the top of the graph. These values are calculated by measuring the return pulse’s width (in nanoseconds) at the desired level. Avg = 81..5 Mhz and below.10. Avg = 355 ns Pulser Voltage : 70 V Pulse Width : 50 ns Primary Gain : 8 dB Secondary Gain : 37 dB Scope Delay : 18. Suite 300.Incorrect assembly .9 -46. max.: (1) (814) 689-1390 Fax: (1) (814) 689-1395 __________________________________________________________________________ Median Waveform The median waveform graph displays a median pulse-echo response (typical) from the test target.0 Mhz Linear Array 64 Housing : Cable Jacket : Cable Length : Connector Type : Active Area Dimensions Length : Elevation : 38.0 1 Elements 64 ____________________________________________ AVG MAX MIN RANGE ______________________________ Center Frequency (MHz) -6dB Bandwidth (%) Vp-p Sensitivity (dB) -20dB Pulse Width (ns) -40dB Pulse Width (ns) 5.6 Freq.4 -45. The reported value is –20 multiplied by the log of the ratio of these two magnitudes. (MHz) –6 dB Percent Bandwidth 1 Elements -6dB % Bandwidth.8 -45. If you have any special testing requirements. 100 V for 10 Mhz and above) . containing characterization records for each probe sold. representing the sensitivity of the probe.4X10-A2-P-2. Half of the return pulses from the probe elements will have a peak-peak voltage greater than (or equal to) this median element. Avg = 5. This value is calculated by using the halfway point (in frequency) of an imaginary line intersecting a given element’s spectrum (FFT) data at the –6 db level. such as –20 dB. PA 16801 USA Tel. The average value of all the probe’s elements is displayed at the top of the graph. Avg = -45. Axial resolution is an important measure of the ability to distinguish individual pulse returns from one another during a normal transducer operation.: (1) (814) 689-1390 Fax: (1) (814) 689-1395 __________________________________________________________________________ Part Number: XAAB-0004 Description: ARRAY. 5-L-64-38.5 Median Waveform (Element 28) 0.4 dB +/. This value is determined by using the length (in frequency) of an imaginary line intersecting a given element’s spectrum (FFT) data at the –6 db level and calculated as a percentage of the center frequency. please contact Olympus.4X10-A2-P-2. The number of the median element is shown above the graph (in parentheses).1 360 880 4.08 83. State College. Pk-to-Pk Sensitivity.024 in) Angle Beam PVC 2. Return pulse duration is shown on the horizontal axis (in microseconds) and amplitude is shown on the vertical axis (in V).9 dB 3.Testing and Documentation All Olympus phased array probes are rigorously tested to ensure conformance to the highest standards. MHz 5.0 Magnitude (dB) Peak-to-Peak Sensitivity The peak-to-peak sensitivity bar graph displays a value for each of the probe’s elements.Poor maintenance .8 % 64 ________________________________________ Part Number: XAAB-0004 Description: ARRAY.4 mm (1.60 mm (0. Standard Test Form A Probe Test Data Sheet is supplied with the purchase of any probe.03 Mhz 81. Suite 300. -48 0 Frequency (MHz) 10 -3.Use of unqualified couplant .5-OM Serial Number: D0259 4.7 us Date : 6/19/2006 Time : 8:25:37 AM Pulse Type : Negative Time (ns) 0 1 Elements -40dB Pulse Width.4 Pulse Width The various pulse-width bar graphs display values representing the axial resolution of the elements’ pulse-echo returns at various levels. All products covered by this warranty must be examined by R/D Tech Ultrasonic transducers and receive their approval in advance before any repairs or replacement are made. PA 16801 USA Tel.0dB (range) –6 dB Center Frequency The –6 dB center frequency bar graph displays a calculated center-frequency value for each of the probe’s elements. com Stock Road.: (44) (0) 1702 616333 505. In both cases. Tel.: (1) 781-419-3900 www. Customized courses can also be arranged. All brands are trademarks or registered trademarks of their respective owners and third party entities.com info@olympusNDT.” This free field guide is available from your local sales representative. Waltham. and concludes with further reference information and a “Phased Array Glossary. boul. This guide begins by explaining what phased array testing is and how it works. Tel. Shinjuku-ku. Tel: (65) 68-34-00-10 PA_Probe_Catalog_EN_201012 • Printed in Canada • Copyright © 2010 by Olympus NDT. then outlines some considerations for selecting probes and instruments. Tel. UK. MA 02453.olympus-ims.: (1) 418-872-1155 31 Gilby Road. Mount Waverly. both for newcomers and for more experienced users who wish to review basic principles. 248373.Training Olympus has recently developed its unique Training Academy. please visit www. consult the ordering information outlined on page 7 and call your local sales representative.com s NDT Field Guide is ISO 9001 and 14001 certified.: (61) 130-013-2992 Valley Point Office Tower. SS2 5QH. Southend-on-Sea. To locate the nearest Olympus office. Victoria. Check the latest course schedule at www. two-week “Level II Phased Array” course.olympus-ims. Tel.com.com Phased Array Testin Basic Theory for ns Industrial Applicatio g Olympus has introduced the new Phased Array Testing field guide as a convenient resource for customers and anyone else interested in phased array technology. students experience practical training utilizing the portable OmniScan® phased array unit. How to Order For pricing or for further information. 3-1Nishi-Shinjuku2-chome. Essex. Tel: 81(0)3-6901-4039 48 Woerd Avenue. du Parc-Technologique. please visit www. Courses range from a two-day “Introduction to Phased Array” program to an in-depth. Courses are currently being offered at the training facilities of participating companies as well as at customer-determined locations worldwide. which is a partnership with major training companies in an effort to offer comprehensive courses in phased array technology and applications. *All specifications are subject to change without notice. Courses lead either to recognized certification or to certificates of attendance. Québec (Québec) G1P 4S9. USA. Shinjuku Monilith. Tokyo 163-0914. 3149. It is designed to be an easy-to follow introduction to ultrasonic phased array testing. To locate the nearest Olympus office. Japan.olympus-ims.olympus-ims. .
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