FR2981454A1 - METHOD AND SYSTEM FOR LASER ULTRASOUND CONTROL OF SPECULAR REFLECTIVITY PARTS - Google Patents

Abstract

The present invention relates to a method for ultrasonic laser testing of specular reflectivity parts comprising: a step of generating a detection laser (10) for reflection on a workpiece (20); . a step of measuring said detection laser (10) reflected on said workpiece (20); characterized in that said measurement is made with two different collection angles, the collection axes being angularly offset and the method implementing two demodulation means (31, 32). The present invention also relates to a laser ultrasonic testing system of specularly reflective pieces.

Description

FIELD OF THE INVENTION The present invention relates to the field of control of the health of structures. BACKGROUND OF THE INVENTION

The present invention relates more particularly to a system and method for ultrasonic laser testing of specularly reflective pieces. The method and system of the present invention are applicable in cases where diffuse reflectivity exists.

A technology called Ultrasonic Laser ("Laser Ultrasonics" or "Laser Based Ultrasound" in English terminology) is used for the control.

STATE OF THE ART In laser ultrasonic testing, a fundamental parameter is the reflectivity of the surface of the controlled part. This reflectivity has a directivity diagram specific to each coating at the wavelength of the laser considered. The light is reflected by the surface, more or less specularly depending on the nature of the surface (depending on the material used and roughness). To carry out ultrasound detection, it is necessary to collect some of this reflected light. The collected light is then directed to an interferometer whose response is analyzed by photodetectors.

In the case of a very specular reflection, the amount of light received by the detectors can cause a saturation of the latter, which leads to errors in the measurement. After the construction of the mappings of the controlled parts, these errors do not make it possible to carry out a reliable diagnosis. Today, non-destructive testing operations performed by laser ultrasound are generally performed with a detection laser whose power is controlled on the amount of light received at the input of the interferometer. In the case of very specular surface, even at minimum power, it may happen that the photodetectors saturate, which makes the measurement difficult to exploit or totally unworkable. In addition, the reaction time of the power modulator can sometimes cause disturbances, the time that the power passes from the maximum position to minimum. DISCLOSURE OF THE INVENTION The present invention intends to overcome the disadvantages of the prior art by proposing a method for measuring an unsaturated signal, even in the case of parts having a very specular surface. To this end, the present invention relates, in its most general sense, to a method of ultrasonic laser testing of specular reflectivity parts comprising: a step of generating a detection laser intended to be reflected on a part; a step of measuring said detection laser reflected on said piece; characterized in that said measurement is made with two different collection angles, the collection axes being angularly offset and the method implementing two demodulation means. Thus, the principle of the double collection makes it possible to dispense with specular reflections that can saturate the detectors.

Preferably, said collection axes are angularly offset by an angle of between five and fifteen degrees. According to one embodiment, said two demodulation means are constituted by two interferometers. According to one embodiment, said two demodulation means consist of a double input interferometer.

According to a variant, said interferometer is a confocal Fabry-Pérot interferometer. According to another variant, said interferometers are photorefractive crystal interferometers.

Advantageously, said method generates two output signals, and these two output signals are digitized and stored. The present invention also relates to a laser ultrasound control system of specular reflectivity parts comprising: means for generating a detection laser intended to be reflected on a part; means for measuring said detection laser reflected on said piece; characterized in that said measurement is made with two different collection angles, the collection axes being angularly offset and said system further comprising two demodulation means.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be better understood by means of the following description, given for purely explanatory purposes, of one embodiment of the invention, with reference to the figures in which: FIG. the system according to the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS OF THE INVENTION FIG. 1 illustrates the system according to the present invention. According to the principle of ultrasound detection by laser ultrasound, when a surface moves, there is a presence of ultrasound and the detection laser light is reflected by said surface and will carry a speed information. The wavelength is slightly shifted if the surface moves. In an interferometer or demodulation means, it is highlighted that the intensity of the transmitted signal is directly proportional to the speed variation (Doppler effect).

Figure 1 shows a detection laser 10 reflecting on a part 20. A measurement with two different angles of collection is performed simultaneously. Thus, if one of the collection axes 51, 52 receives a specular reflection having the damaging effect of the saturation of the detector, then the other axis will see a diffuse reflection more conducive to a measurement. It is therefore fundamental that the two collection axes are angularly offset by an angle, preferably but not exclusively between five and fifteen degrees, but it is necessary that they observe the same point of measurement. This solution also requires the implementation of two demodulation means 31, 32 shown in Figure 1, that is to say two interferometers or a dual-input interferometer. These interferometers may for example be confocal Fabry-Perot interferometers (that is to say interferometers equipped with two confocal mirrors used either in reflection or in transmission - the wave interfering with itself in a cavity and intensity transmitted at the output in this type of interferometer depending on the wavelength of the incoming light), or photorefractive crystal interferometers.

Both output signals 41 and 42 are digitized and stored. Finally, it is the signal from the unsaturated detector that will be retained for the measurement. The electrical signal obtained at the output is unsaturated. There is no glare, unlike the state of the art.

Thus, in the great majority of cases of application, one will obtain at each point of measurement a signal which will not be saturated, which could not be obtained in the case of a simple collection. Indeed, thanks to the present invention, if a collection angle is in the specular range, the other collection angle will not be because the two angles are offset.

The system according to the present invention and the method according to the present invention are intended to be implanted in ultrasonic laser measurement systems. Collection optics must be duplicated and staggered. We then identify a main collection axis and a secondary collection axis.

The collected light must be used in the same way as in the previous case with a simple collection, that is to say that the collected light is analyzed in an interferometer in order to convert the vibrations of the surface into an electrical signal which reflects the variations of the ultrasonic wave. This is applied on both collection axes. The signal obtained is digitized and stored. It follows an analysis of the saturation of the detectors and in case of saturation of the main detector, it is the signal from the secondary detector which is taken into account in the construction of cartographies. At the output of the two demodulation means 31, 32 or interferometers, the light intensity varies as a function of the wavelength of the light beam analyzed. However, the wavelength is proportional to the speed of movement of the ultrasound. So, in case of movement of the surface that reflects the laser beam, the intensity varies. A photodiode is placed at the output of the interferometer, this photodiode allowing the conversion of photons into electrons, and an electrical signal is thus obtained. Thus, we have an electrical signal as a function of time ("A-scan" in the terminology of Non-Destructive Testing or NDT), this signal being equivalent to that obtained by a conventional method of ultrasonic control.

The present invention applies advantageously, but not exclusively, to composite parts. The users of this system are the technicians in charge of the quality control of the fabrications. However, this system can be completely transparent to the user. This is an improvement that can be integrated by Laser Ultrasonic Systems suppliers / integrators. The invention is described in the foregoing by way of example. It is understood that one skilled in the art is able to realize different variants of the invention without departing from the scope of the patent.

Claims (8)

REVENDICATIONS1. A method of ultrasonic laser testing of specular reflectivity parts comprising: - a step of generating a detection laser (10) for reflection on a workpiece (20); a step of measuring said detection laser (10) reflected on said piece (20); characterized in that said measurement is made with two different collection angles, the collection axes (51, 52) being angularly offset and the method using two demodulation means (31, 32). 2. Method according to claim 1, characterized in that said collection axes (51, 52) are angularly offset by an angle (a) between five and fifteen degrees. 3. Method according to claim 1 or 2, characterized in that said two demodulation means (31, 32) consist of two interferometers. 4. Method according to claim 1 or 2, characterized in that said two demodulation means (31, 32) are constituted by a dual input interferometer. 5. Method according to claim 4, characterized in that said interferometer is a confocal Fabry-Perot interferometer. 6. Method according to claim 3, characterized in that said interferometers are photorefractive crystal interferometers. 7. Method according to any one of the preceding claims, characterized in that it generates two signals (41, 42) at the output, and in that these two output signals (41, 42) are digitized and stored. 8. Laser ultrasonic testing system specular reflectivity parts comprising: - means for generating a detection laser (10) for reflection on a part (20); means for measuring said detection laser (10) reflected on said piece (20); characterized in that said measurement is made with two different collection angles, the collection axes (51, 52) being angularly offset and said system further comprising two demodulation means (31, 32).