Transducer Selection Criteria—Europ

Transducer Selection Criteria—European Standards
For transducers manufactured to European standards, technical and performance information is provided throughout this catalog
based on the definitions below. A comprehensive data sheet is supplied with most flaw detection transducers at no charge.
Description Explanation
Element size D or a x b Diameter D or length x width a x b of the transducer element. The size of the element strongly affects the shape of the
transmitted sound field. Slight deviations, (e.g., imperfect shape or positions with reduced radiation due to poor bonding)
cause considerable evaluation errors, even when calibrated to a reference flaw.
Nominal frequency f The mean frequency of all probes of the same type. The frequency has a great influence on the evaluation of reflectors.
Even the shape of the sound field and the reflection behaviour of angled reflectors are strongly dependent on the
frequency. With increasing frequency, the echo height from non-vertically positioned reflectors to the sound beam
decreases. This is why each probe is checked by our Quality Control to see if its frequency coincides with the nominal
frequency, according to the identification label, within very narrow tolerances. This is entered into the probe data sheet.
Bandwidth B The range of frequencies in the echo pulse whose amplitude, at the most, is 6 dB less than the maximum amplitude.
fo - fu
B = ------------ X 100%
f
fo = upper, fu = lower frequency limit for a 6 dB drop in amplitude.
With B = 100%, a 4 MHz, probe for example, has an fo of 6 MHz and an fu of 2 MHz. Large bandwidths mean shorter echo
pulses, which mean high resolution and a good penetration power, because the lower frequencies of the pulse become less
attenuated than the nominal frequency. At high attenuation, the frequency of reflected signals decreases, compared to the
nominal frequency, as the distance increases. This must be taken into account with flaw evaluation. The bandwidth of each
probe is therefore checked and must, within narrow tolerances, coincide with the mean value of all probes.
Focal distance F
Near field length N
The distance of a small reflector from the probe producing the highest possible echo. Probes are focused in order to detect
small reflectors and produce a high echo amplitude. Focusing is only possible within the near field of the probe.
The near field length N is the focal distance of the unfocused probe which constitutes the sound pressure maximum at the
largest distance from the probe. N is determined by D, c and f.
D2
eff D2
eff . f
For D >> λ is: N = --------- = -------------
4 λ 4 c
λ = wave length c = sound velocity Deff = effective element diameter
Focal point and near field length are the distances with the best sound concentration and reflector recognition. Therefore,
when a probe is selected for a critical test, the flaw expectancy range must be in the focal area or near field length. The
data in the tables refers to steel with the exception of immersion testing in water.
Focal diameter FD6 Diameter of the sound field in the focal distance or near field length with a 6 dB drop of the echo indication.
F . c 1 F
For D >> λ is: FD 6 = ------ = ---- k . D eff with k = -----
f - Deff 4 N
Pulse shape The presentation of signals, as they are at the instrument input coming from plane reflectors.
Spectrum Display of all the frequencies in the echo pulse. The frequency amplitudes are shown over the frequency.
Beam angle ß The angle between the main beam and the normal axis of the test surface.