FR2677185A1 - LASER TRANSMITTER IN PARTICULAR FOR THE GENERATION OF ULTRASONIC WAVES AND ITS APPLICATION TO A NON-DESTRUCTIVE NON-CONTACT CONTROL DEVICE. - Google Patents

Abstract

A laser transmitter particularly intended for generating controlled-directivity ultrasonic waves, and comprising, inter alia, an optical cavity resonator (10) made up of two plane and parallel mirrors (11, 12) of which one (11) is completely reflective while the other (12) is partially reflective, as well as a laser generator (20) placed between said mirrors for transmitting radiation (R) perpendicularly thereto and exiting through mirror (12), wherein said generator (20) consists of plates (200) made of an active material and directed in such a way that the longitudinal axes thereof are perpendicular to said mirrors, said plates being attached to one another, and wherein a multiple-contact synchronising switch (30) is arranged between the generator (20) and the completely reflective mirror (11) to cause sequential plate emission (200). The laser transmitter may be used in nondestructive tests, in particular those using thermoelasticity or ablation.

Description

 The present invention relates to laser transmitters and, more particularly, to a laser transmitter in particular for the generation of ultrasonic waves with controlled di rectivity and the application of such a transmitter to non-destructive testing devices.

 The value of non-destructive testing of materials and products is no longer to be demonstrated. Many technical sectors use non-destructive testing, for example using ultrasound, to check the quality and / or condition of basic materials or manufactured products.

 This is for example the case of the steel industry for the verification of long and / or flat products and also the case of the aeronautical industry to ensure the quality of complex parts during manufacture or later, after use, to ensure that their aging does not risk compromising safety.

 However, the use of ultrasound for non-destructive testing poses problems which sometimes seriously limit its practical applications since it is very often necessary to ensure physical coupling, for example using a liquid, to maintain acoustic continuity between transmitters or receivers, on the one hand, and the verified product, on the other.

 Attempts have been made to overcome this obligation from the use of such a coupling and thus succeed in making non-destructive checks using ultrasound without physical contact by using sources of impulse radiation. such as lasers to generate ultrasound. Not only does such an emission of ultrasound pose problems but also their subsequent detection, after reception by the product to be checked.

 One of the main difficulties is due to the relatively low acoustic power of the ultrasonic waves induced by laser radiation, which must be used if the operating regime is to ensure that the behavior of the product to be ultrasonic preferably remains in the thermoelastic limit so as not to alter the surface condition. As moreover, the surface condition of the product to be checked is rarely comparable to that resulting from an optical polish, additional difficulties appear for the detection that even fine optical techniques using heterodyne interferometry do not easily allow solve for sure. Indeed, the surface state not perfectly smooth causes a modulation of the amplitude of the signal detected by speckle effect.

 In an attempt to resolve some of these difficulties, it has been proposed to deposit the energy radiated by a laser transmitter on the product to be checked in the form of a succession of impacts obtained using an acousto-optical deflector. But it appeared that this technique is not very reliable due to its lack of fidelity, the relatively short longevity of the laser sources used as well as the low rates of implementation. With regard to detection, it has also been proposed to use a receiver comprising a MACH-ZEHNDER type interferometer equipped with an acousto-optical modulator making it possible to operate in heterodyne mode.

 None of these attempts is entirely satisfactory because of its cost of implementation and of its practical difficulties of use which limit its use in the laboratory, which prohibits practically any industrial use for routine checks.

 The object of the invention is to remedy most of the drawbacks listed above using a solution which does not use scanning techniques.

 The subject of the invention is a laser emitter in particular for the generation of ultrasound waves with controlled directivity consisting, inter alia, of a resonant optical cavity made of two parallel plane mirrors, one of which is completely reflecting and the other partially reflecting and of a laser generator placed between these mirrors to emit radiation normal to the mirrors and emerge through the partially reflecting mirror. This emitter is particularly characterized in that this generator is composed of plates of active material which are oriented in such a way that their longitudinal axes are perpendicular to these mirrors and which are contiguous to each other, and in that it comprises a multiple synchronization switch interposed between the generator and the totally reflecting mirror to cause the sequential emission of the plates.

 The subject of the invention is also the application of such an emitter to a device for the non-destructive testing of a sample so as to irradiate the latter and preferably to generate in particular expansions by thermoelastic effect in order to be able to know it. contactless behavior.

 Other characteristics of the invention will emerge from the reading of the description and the claims which follow as well as from the examination of the appended drawing given only by way of example where the single figure schematically illustrates in perspective an embodiment of a transmitter according to the invention.

 Since the techniques relating to laser transmitters and more particularly relating to those of them used for generating ultrasonic waves are well known in the art, we will only describe below what relates directly or indirectly to the invention. For the rest, the specialist in the technique considered will draw on the current conventional solutions at his disposal to deal with the particular problems with which he is confronted.

 In what follows, the same reference number always identifies a homologous element, whatever the embodiment, or its variant of execution, of the invention.

 For the convenience of the description, each of the constituents of the invention will be described successively before explaining its operation.

 As can be seen by examining the figure, the schematically drawn embodiment of a laser transmitter for the generation of ultrasound waves with controlled directivity according to the invention, consists, inter alia, of a resonant optical cavity 10 made of two mirrors II and 12. These mirrors are parallel planes and such that one, the mirror 11 is fully reflecting and the other the mirror 12 is partially reflecting.

A laser generator 20 is placed between the mirrors 11 and 12 to emit laser radiation R which is normal to the mirrors 11 and 12 and which emerges through the partially reflecting mirror 12. This generator 20 is composed of plates, bars, bars or the like 200, of active material, which are oriented so that their particular longitudinal axes are perpendicular to the mirrors 11 and 12, and which are joined to each other as is apparent from the 'examination of the drawing. The plates or the like 200 are preferably parallelepipeds with a rectangular base 201 and which are oriented obliquely at the angle of BREWSTER, with respect to the optical axis defined by the mirrors 11 and 12. As can be seen 'Observe, the plates are joined to each other by their lateral faces 202. As can also be observed, the coplanar free faces 203 of the plates 200 are equipped with laser diodes 21 to ensure the optical pumping of the plates 200. It is possible to also use conventional flashlights. The other coplanar free faces 204 of the plates 200 are provided, if necessary, with a radiator 22 for removing heat produced during operation. For example, a water or PEL effect radiator is used
THIRD.

 The laser transmitter according to the invention also comprises a multiple synchronization switch 30 interposed between the generator 20 and the fully reflecting mirror 11 to cause the sequential emission of each of the bars 200. Preferably, this multiple synchronization switch 30 is constituted POCKELS cells 300 each of which is associated with one of the plates 200 as illustrated.

 In addition, as is conventional for this type of transmitter, a polarizer 40 is interposed between the generator 20 and the optical switch 30, as shown.

A supply circuit 50, only illustrated diagrammatically, controls the operation of the generator 20 and of the switch 30. To do this, this circuit is connected to each of the cells
POCKELS 300 and to each of the laser diodes 21 which are used for the optical pumping of the active plates.

This type of circuit is conventional and for this not illustrated in detail. This circuit is, for example, under the dependence of a programmable microcomputer.

 In this way, the switch 30 fixes the order, the duration and the power of the sequential emission of each of the plates.

 Preferably, the transmitter according to the invention comprises for example at least sixteen plates. These plates consist of the active material YAG composed of a matrix Y3A15012 doped with the Nd3 + ion emitting at 1064 nm. It is also possible to use as active material plates of other matrices doped with trivalent ions.

 The operation of the transmitter is such that the sequential emission of the plates is manifested in the form of a train of pulses of adjustable frequency each of which, preferably, has a duration of less than 15 ns and a repetition frequency of l 'order of 30 to 50 Hz or even some 100 Hz. The minimum total energy used is of the order of 200 mJ.

Each plate emits a beam whose diameter is of the order of 4 mm and whose divergence is of the order of 1 mrad. In this way, a total spatial extension of the sources of about 3 cm is obtained and an emission with a well-defined directivity diagram, with marked asymmetry and without secondary lobe.

 In order to ensure the distribution of light energy in this "acoustic pupil" composed of a set of thermoelastic sources whose lateral dimension is variable, an anamorphoser is used. This anamorphic lens, which acts on the elementary, cylindrical and parallel beams, preferably comprises cylindrical focusing lenses and a variable focal length lens which transforms beams into equidistant lines.

 We make sure that each pulse has a uniphase spatial distribution. The peak value of the power is adjustable between a few kilowatts and a few megawatts.

 We make sure, if necessary, that the emission power of each plate is adjustable separately.

 It can therefore be seen that, thanks to the invention, it is possible to produce a laser transmitter for the generation of ultrasonic waves with controlled directivity which operates entirely remotely and without contact thanks to judiciously controlled laser beams which make it possible to operate in particular in thermoelastic regime of the product irradiated with ultrasounds of sufficient power.

 It goes without saying that this laser emitter according to the invention can be used to emit a significantly higher incident energy in order to operate in ablation regime with surface vaporization of the material and no longer dilation as in thermoelastic regime.

 Such a laser transmitter according to the invention is particularly suitable for a device for non-destructive testing, in particular in hostile environments or for online manufacturing processes.

 The above clearly highlights the features and advantages of the invention.

Claims (15)

 1 - Laser emitter in particular for the generation of ultrasonic waves with controlled directivity consisting, inter alia, of a resonant optical cavity (10) made of two mirrors (11, 12) parallel planes of which one (11) is completely reflecting , and the other (12) partially reflecting and of a laser generator (20) placed between these mirrors to emit radiation (R) normal to the mirrors and emerge through the partially reflecting mirror (12), characterized in that this generator (20) is composed of plates (200) of active material which are oriented in such a way that their longitudinal axes are perpendicular to these mirrors and which are attached to each other, and in that it comprises a multiple switch (30) synchronization interposed between the generator (20) and the fully reflecting mirror (11) to cause the sequential emission of the plates (200).  2 - Transmitter according to claim 1, characterized in that the multiple switch (30) is an optical switch (30) with cells (300) of POCKELS.  3 - Transmitter according to one of claims 1 and 2, characterized in that the plates (200) are parallelepipeds with bases (201) rectangular and in that each of these faces cut at the angle of Brewster (201) faces obliquely to one of these mirrors (11, 12).  4 - Transmitter according to any one of claims 1 to 3, characterized in that the multiple switch (30) fixes in a programmable manner the order, the duration and the power of the sequential emission of each of the plates ( 200).  5 - Transmitter according to any one of claims 1 to 4, characterized in that each plate (200) is provided with a laser diode (21) for its optical pumping and in that these diodes are mounted on the faces (203) free coplanar of the plates (200).  6 - Transmitter according to any one of claims 1 to 5, characterized in that the free faces (204) coplanar plates (200) are provided with a radiator (22) to remove the heat produced in operation.  7 - Transmitter according to any one of claims 1 to 6, characterized in that the plates (200) are made of active material YAG composed of a matrix Y3A15012 doped with the ion Nd3 +.  8 - Transmitter according to any one of claims 1 to 6, characterized in that the plates (200) are made of a matrix doped with trivalent ions.  9 - Transmitter according to any one of claims 1 to 8, characterized in that the number of plates (200) is at least equal to sixteen.  10 - Transmitter according to any one of claims 1 to 9, characterized in that the sequential emission of the plates (200) is made of a train of pulses of adjustable frequency each of which has a duration of less than 15 ns, a repetition frequency of the order of 30 to 50 Hz and a minimum total energy of 200 mJ.  11 - Transmitter according to any one of claims 1 to 10, characterized in that the sequential transmission at a peak power of between approximately 100 kW and approximately 100 MW.  12 - Transmitter according to claim 10 and / or 12, characterized in that each pulse has a uniphase spatial distribution.  13 - Transmitter according to any one of claims 1 to 12, characterized in that the emission power of each plate (200) is adjustable separately.  14 - Transmitter according to any one of claims 1 to 13, characterized in that it comprises an anamorphoser to ensure the distribution of light energy in an acoustic pupil.  15 - Application of a transmitter according to any one of claims 1 to 14 to a device for irradiating a sample in order to generate expansions by thermoelastic effect so as to be able to know its behavior without contact, by a non-destructive test .