Estimating the Parameters of Signals Observed during Ultrasonic Testing of a Cylindrical Article with a Normal Probe on the End Surface

Danilov, V. N.

doi:10.1007/s11181-005-0135-4

Cited by 4 publications

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“…The relationship obtained in [5] between pressure δ P bc of the bottom echo signal in a cylindrical article and pressure δ P bp of the bottom echo signal reflected from an infinite plane boundary can be expressed as (1) In formula (1), a is the radius of a round-shaped normal probe,…”

Section: Acoustic Methodsmentioning

confidence: 99%

“…For the axles of railway vehicles subjected to the acceptance inspection, their "sounding" is estimated according to the document êÑ 32.144-2000 [4] by the difference between the bottom echo signals received from the face of a CO-2 (calibration block) sample (from a 59-mm distance) and the butt end of the axle. However, as was mentioned in [5], during detecting of a bottom echo signal reflected from the end surface using a normal probe that is attached to the opposite end surface of the cylindrical article at its center and creates pressure P acting normally on the surface (Fig. 1), it is rather difficult to estimate the signal level because it is determined not only by article length h (distance from the reflecting end) but also by ratio b / h , where b is the radius of the cylinder.…”

mentioning

confidence: 88%

“…1), it is rather difficult to estimate the signal level because it is determined not only by article length h (distance from the reflecting end) but also by ratio b / h , where b is the radius of the cylinder. If b decreases to values several times smaller than the radius for the first Fresnel zone [6] of the operating wavelength of the normal probe or even smaller, the amplitude of the bottom echo signal will decrease.In [5], an expression was obtained for the pressure applied to a normal probe by longitudinal waves forming a bottom echo signal. This expression is expressed as a sum of pressures created by a wave reflected from an infinite plane boundary and a wave reflected from the angle between a cylinder's lateral surface and end surfaces over the entire round profile.…”

mentioning

confidence: 99%

“…In [5], an expression was obtained for the pressure applied to a normal probe by longitudinal waves forming a bottom echo signal. This expression is expressed as a sum of pressures created by a wave reflected from an infinite plane boundary and a wave reflected from the angle between a cylinder's lateral surface and end surfaces over the entire round profile.…”

mentioning

confidence: 99%

“…In [5], this dependence was considered for the case of a continuous operating regime (at a nominal frequency) of a normal probe. The objective of this study was to understand the specifics of changes in the bottom echo-signal level reflected from the plane surface of a cylindrical article in the pulsed mode.…”

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confidence: 99%

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Estimation of a Bottom Echo-Signal Level Reflected from a Plane Surface of a Cylindrical Article Using a Normal Probe Operating in a Pulsed Mode

Danilov

2005

Russ J Nondestruct Test

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The influence of the pulsed operating mode on a bottom echo-signal level reflected from a plane surface of a cylindrical article is studied during variations in the article's radius. It is shown that the pulsed character of a signal smoothens this function significantly as compared to that in the previously computed continuous mode. Numerical estimates of the bottom echo signal have been made for the ultrasonic inspection of wheel-pair axles of railway vehicles.During testing of a cylindrical article with a normal probe, the amplitude of a bottom echo signal (from the opposite end surface) can be used as a reference level to establish the required sensitivity of a flaw detector designed to find flaws with a certain equivalent area according to a DGS diagram [1][2][3]. For the axles of railway vehicles subjected to the acceptance inspection, their "sounding" is estimated according to the document êÑ 32. 144-2000 [4] by the difference between the bottom echo signals received from the face of a CO-2 (calibration block) sample (from a 59-mm distance) and the butt end of the axle. However, as was mentioned in [5], during detecting of a bottom echo signal reflected from the end surface using a normal probe that is attached to the opposite end surface of the cylindrical article at its center and creates pressure P acting normally on the surface (Fig. 1), it is rather difficult to estimate the signal level because it is determined not only by article length h (distance from the reflecting end) but also by ratio b / h , where b is the radius of the cylinder. If b decreases to values several times smaller than the radius for the first Fresnel zone [6] of the operating wavelength of the normal probe or even smaller, the amplitude of the bottom echo signal will decrease.In [5], an expression was obtained for the pressure applied to a normal probe by longitudinal waves forming a bottom echo signal. This expression is expressed as a sum of pressures created by a wave reflected from an infinite plane boundary and a wave reflected from the angle between a cylinder's lateral surface and end surfaces over the entire round profile. The second part can be regarded as a correction which influences the amplitude of the bottom echo signal owing to the reflecting area being limited by the lateral surface.It is very important to take into account the level of the bottom echo signal depending on ratio b / h when a bottom echo signal is used as a reference signal during work with the DGS diagrams. In [5], this dependence was considered for the case of a continuous operating regime (at a nominal frequency) of a normal probe. The objective of this study was to understand the specifics of changes in the bottom echo-signal level reflected from the plane surface of a cylindrical article in the pulsed mode. The results are discussed below. Figure 2 shows (in arbitrary units) a bottom echosignal pulse in a steel sample detected from a 200-mm distance, which is taken from the computer display of an ÄÇÉìê system for a èêàá Ñ 11 è 111-2.5-ä 12-002 ...

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Section: Acoustic Methodsmentioning

confidence: 99%

mentioning

confidence: 88%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Estimation of a Bottom Echo-Signal Level Reflected from a Plane Surface of a Cylindrical Article Using a Normal Probe Operating in a Pulsed Mode

Danilov

2005

Russ J Nondestruct Test

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Effect of the Size of a Flat-Bottom Hole in a Cylindrical Specimen on the Bottom-Signal Level

Danilov¹

2005

Russ J Nondestruct Test

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The effect of a change in the size of a flat-bottom hole on the level of a bottom signal measured with a normal probe at an end surface of a cylindrical specimen is considered. It is shown that this effect depends on the specimen's radius-to-length ratio. It is established that the difference in the levels of a bottom signal and a signal from a hole in the specimen is in good agreement (within 0.5 dB) with the corresponding difference obtained from the calculated DGS diagram.During ultrasonic inspection of forged pieces, rods, etc., with normal probes aimed at the tuning of the sensitivity of flaw detectors and evaluation of the equivalent area of flaws, a common practice is to use cylindrical calibration blocks with artificial reflectors in the form of flat-bottom holes, the planes of which are oriented perpendicularly to the ultrasonic-beam propagation [1]. Such reflectors are manufactured in the form of holes with flat profiles at different depths, axially symmetric with respect to the specimens. Reliable time selection of signals from flat-bottom reflectors against the background of a bottom signal from the specimen's surface, which is opposite to the surface of emission, and reception of a longitudinal wave can be achieved at typical distances from the reflectors to the former surface (the depth of the hole) of 15-20 mm. An example of specimens with such reflectors is a KCO-2 kit of calibration blocks (GOST (State Standard) 21397-81) used in ultrasonic testing of intermediate products and articles from aluminum alloys [2]. Analogous specimens are also produced from steel with allowance for the requirements of the above standard [1]. Specimens undergo primary and periodic certification (upon production and during service, respectively) to check the correspondence of their parameters to the required standards. In order to ensure the uniformity of measurements in the determination of the echo-signal amplitudes from the specimen's flatbottom reflectors, it is necessary to choose a reference signal, the amplitude of which must be compared to the signal amplitudes from the reflectors. For a KCO-2 kit, it was proposed to use an echo signal from a steel ball in an immersion bath as the reference signal, which is used to adjust the bath's elements and calibrate the flawdetector's sensitivity [3]. The normalized signal levels obtained are compared to the rated values, the tolerable deviations from which are ± 2 dB at most. The necessity of performing rather laborious measurements using a special-purpose setup makes the monitoring of signal levels from the reflectors impracticable not only during operation but also during periodic certification of specimens by metrological agencies.One of the methods for substantially simplifying the determination of the correspondence of signals from flat-bottom reflectors to the rated values is their comparison with the levels of the bottom signals in the same specimens, which are measured at such a position of a normal probe in which the maximum signal from a given reflector is achi...

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Calculation of echo signals from a flat-bottom hole for normal probes

Danilov

2007

Russ J Nondestruct Test

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Estimating the Parameters of Signals Observed during Ultrasonic Testing of a Cylindrical Article with a Normal Probe on the End Surface

Cited by 4 publications

References 1 publication

Estimation of a Bottom Echo-Signal Level Reflected from a Plane Surface of a Cylindrical Article Using a Normal Probe Operating in a Pulsed Mode

Estimation of a Bottom Echo-Signal Level Reflected from a Plane Surface of a Cylindrical Article Using a Normal Probe Operating in a Pulsed Mode

Effect of the Size of a Flat-Bottom Hole in a Cylindrical Specimen on the Bottom-Signal Level

Calculation of echo signals from a flat-bottom hole for normal probes

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