FR2752300A1 - Buried gas pipe electromagnetic detector - Google Patents

Abstract

The device includes an emitter (20) with an aerial (21) which generates an electromagnetic wave (12) focused by a lens (22) onto a solid or liquid medium (11). The electromagnetic wave propagates through the medium and reaches the surface of an absorbing object (10). The wave is absorbed by the object producing its local heating. As a result the object surface generates an acoustic wave (14). The acoustic wave propagates through the medium and is detected by a number of sensors. These sensors can detect either the acoustic wave or the temperature.

Description

METHOD AND DEVICE FOR CHARACTERIZING A
SOLID OR LIQUID MEDIUM
DESCRIPTION
Technical area
The present invention relates to a method and a device for characterizing a solid or liquid medium.

 The field of the invention is in particular that of the location of objects located in a solid or liquid volume, and in particular that of the location of pipes buried at short distances, for example less than a few meters gas, water, oil. ...

State of the art
Devices of the prior art are described in articles referenced [1], [2] and [3] at the end of the description. They relate to the following prior art techniques
Seismic: we send a high energy seismic wave to the surface of a volume to be analyzed, we then measure the reflected energy. The implementation of such a technique is complex.

 Electromagnetic: we analyze the absorption by an object of an emitted electromagnetic wave. We obtain a localization of the object in a plane, but not a localization in depth. In-depth information requires the use of sophisticated processing. In fact, to improve resolution, electromagnetic techniques use complex processing methods which require knowledge of the properties of the object to be located.

 Radar: we use an echo technique: we send a first pulse and we recover a second pulse. To obtain the desired information, the pulse duration must be less than the travel time. For depths less than a meter, the travel times are of the order of a nanosecond, even a picosecond, which is difficult to obtain. Radar techniques limit the use of processing methods, but are difficult to implement due to very short propagation times, which implies the use of very short duration pulses of the order of a nanosecond, even picosecond, difficult to control, hence very average spatial resolutions. In this case the penetration depth is limited from one to three meters. In the case of a liquid target, the radar range is of the order of a meter, but it does not see small amounts of liquid.

 Magnetostatic: we measure the variations of magnetic induction by using an object. The observation of variations can be linked to the presence of an object with magnetic behavior.

 The propagation of acoustic waves (elastic, ultrasonic) in materials is a phenomenon widely used in particular in non-destructive testing. This characteristic of the materials is interesting since it allows the exploration of the core of the solid without any deterioration. It is particularly known for isotropic and homogeneous materials.

 Generally, the method used, based on the propagation of acoustic waves, consists in generating a wave at a point on the surface of the material (by a Transmitter) and, listening to the wave at another point (Receiver). The study of the material transfer function (relationship between the emitted wave and the received wave) allows to know the structure of the material crossed by the wave. This analysis can be used to determine the characteristics of the material, or, in non-destructive testing (NDT) to determine the presence of defects that can appear when the material is subjected to stresses. Indeed, the presence of faults and discontinuities leads to wave diffractions.

 The application of acoustic emission to the control and study of the mechanical behavior of a unidirectional composite material is described in the article referenced [4].

 When a material is deformed, rupture mechanisms occur locally. These irreversible and brief phenomena can be microscopic (micro deformations) or more important (crack propagation). This results in a discontinuity of the field of displacements. This discontinuity called event is the source of a deformation wave propagating in the material. On the surface, a suitable sensor (acceleration sensor of the piezoelectric type) receives and then translates this wave (transient mechanical vibration) into an electrical signal of the damped sinusoidal burst type.

 The processing of these acoustic emission signals consists in extracting information therefrom in relation to the breaking mechanisms. Processing methods are signal processing methods.

 In the devices of the prior art, the means employed are particularly faulty by their complexity of implementation (seismic, acoustic), by their lack of depth resolution (electromagnetism and magnetostats) and by the risks of glare (radar).

 The object of the invention is to overcome the drawbacks defined above and to allow the characterization of a solid or liquid medium by a simple device having good spatial resolution.

Statement of the invention
The invention provides a method for characterizing a solid or liquid medium, characterized in that it comprises the following steps
- emission of an electromagnetic wave towards a surface of a studied volume and scanning of said volume by the electromagnetic wave
- detection on the surface of an acoustic wave and / or a thermal wave from the volume studied.

 The present invention also provides a method of detecting an object in this solid or liquid medium, this object having an electromagnetic absorption different from that of said medium.

 Advantageously, the electromagnetic wave can be focused on the surface of the volume to be observed. It is also possible to detect a thermal wave at the surface. We can also modulate the electromagnetic wave.

 According to the method of the invention, the medium to be analyzed is disturbed by emitting an electromagnetic wave, the object, for example made of metal, or any object having an electrical conductivity different from that of the medium, absorbs energy, its temperature increases and there is expansion or appearance of cracks or production of a relative movement between the medium and the object resulting in the production of an acoustic wave. From the measurement of this acoustic wave, the situation of the object is determined.

 In the case where the object is covered with water, the rise in temperature produces a vaporization of the water, which results in a rise in the local pressure, which in turn generates an acoustic wave.

 The invention makes it possible in particular to carry out investigations at depths less than one meter.

 The invention also proposes a device allowing the implementation of the preceding method which comprises a modulated electromagnetic source radiating in a solid or liquid medium, at least one acoustic detector and possibly one or more thermal detector (s) and / or acoustics (s) coupled to this medium, and a scanning system. It can also include a system for focusing the electromagnetic wave. The acoustic or thermal detectors can be synchronized, with a controllable delay, to the pulsed electromagnetic source. The electromagnetic signal can be swept.

The invention allows the monitoring of inaccessible areas located for example
- in nuclear power plants
- in submerged offshore structures
- in tanks.

Brief description of the drawings
- Figure 1 illustrates the method of the invention in the case of an absorbent object located in a solid or liquid medium less absorbent than this
- Figure 2 illustrates a first variant of the device of the invention comprising focusing and scanning
- Figure 3 illustrates a second variant of the device of the invention without focusing.

Detailed description of embodiments
The invention provides a method for producing an acoustic wave in a non-destructive manner.

 In the prior art, the emission of an acoustic wave is carried out using mechanical stresses applied to materials such as the introduction of a pin for example.

 In the invention, the electromagnetic wave is focused on the surface of the volume to be analyzed and the acoustic wave is detected on the surface. The study of the acoustic wave emitted by a medium as a function of the focal point is a means of characterizing the medium.

The method of the invention comprises
means for emitting an electromagnetic wave, these means being located outside in the case of a solid medium, outside or inside in the case of a liquid medium
- Acoustic and / or thermal detection means, located on the external wall of the medium in the case of a solid medium, on the external wall and or in the medium in the case of a liquid medium.

 Figure 1 illustrates the basic concept of the invention. A solid or liquid medium 11, which receives an electromagnetic wave 12, is subjected to a local rise in temperature 13, the electromagnetic energy absorbed being transformed into heat which results in local heating, and produces an acoustic wave 14.

 As in the embodiment illustrated in this FIG. 1, one can also have, in addition, an absorbent object 10 placed in the medium 11, which is less absorbent than the object.

 The method of the invention uses the conjunction of signals of different nature, in particular electromagnetic, thermal, and acoustic signals. Due to their different nature, interference between signals is limited. In addition, the speed of propagation of the acoustic wave being much lower than that of the electromagnetic wave, its propagation time is therefore greater, which allows, in an echo technique, to separate well in time the reception of the broadcast.

Two techniques can be used to detect the local temperature rise 13
Direct detection of temperature variation by the use of one or more thermometers coupled to the medium. In this case the thermometers see a variation of the temperature, of course damped compared to that at the focus point.

 Detection by means of one or more acoustic sensors placed on the surface, local heating can result in different phenomena which can generate an acoustic wave 14 which after propagation in the medium can be detected.

 Thus, as illustrated in FIG. 2, in a first variant, the device of the invention comprises a transmitter 20 which controls an antenna 21 emitting an electronic wave, which is focused by passing through a lens 22, at least one temperature sensor 23 connected to a thermal detection device 24 receiving a synchronization signal from the transmitter, and at least one acoustic sensor 25 connected to an acoustic detection device 26 also receiving a synchronization signal from the transmitter.

The phenomena of production of the acoustic wave, due to heating, can be
- local thermal expansion
- the formation of cracks
- a relative displacement with friction
- a local and sudden increase in pressure following the vaporization of a liquid, or even the melting or vaporization of a solid.

Detection sensors can be of different types
- microphones
- seismic
- thermometers.

 In this variant the electromagnetic signal is focused by the lens antenna system (21, 22). The antenna 21 and the lens 22 form a movable focusing assembly at (x, y, z). The scanning of the volume to be explored is carried out by combined movements of these components.

 The spatial resolution r is related to the frequency f of the signal by the Fresnel relation, r = 1.22 v / f sine, where v is the speed of the electromagnetic signal and O the opening angle of the lens.

 For a resolution of a few centimeters the frequency is around Ghz. This resolution corresponds to the transverse resolution. On the other hand, the longitudinal resolution is better, of the order of a few millimeters.

 The electromagnetic signal modulated in sinusoidal form or in the form of pulses can also be swept, which makes it possible to optimize its propagation or its absorption (in fact spectrometry is carried out) and therefore to have access to certain properties of the object. .

 The advantage of using an electromagnetic wave on emission is that this wave can propagate in media with limited electrical conductivity and magnetic permeability, which is the case in many media. In addition, this wave can be focused.

 Depending on the properties of the medium, the electromagnetic wave is more or less absorbed. For a homogeneous medium, the energy density absorbed is maximum at a focal point. In the case, for example, of the transition from a non-absorbent medium to an absorbent medium, the variation in the energy density absorbed at the focusing point is significant. The detection of this variation makes it possible to locate the change in environment. If we perform a space scan we can thus define the local geometry.

 The variation of the absorbed energy translates from the electromagnetic point of view by a variation of the charge which could be used to detect the changes of medium, but the current detection means are not sensitive enough to use such a phenomenon.

 The technique developed above is applicable in different configurations since it is based on the difference in absorption between the surrounding medium and the object to be viewed.

 Thus, for example, in a second variant of the device of the invention, the latter, as shown in FIG. 3, is a device without focusing. It includes, as in the device in FIG. 2, a transmitter 20, an acoustic sensor 25 connected to an acoustic detection device 26.

 It does, however, include a mobile antenna 30 at (x, y, z).

 In this variant embodiment, the electromagnetic signal is not focused but only pulsed. In this case the presence of a discontinuity in the properties of the medium can result in an increase in the absorption of the signal, hence a local rise in temperature which can also cause an acoustic pulse. The detection of this pulse and in particular the measurement of the time interval between it and the electromagnetic pulse makes it possible to locate the discontinuity in a direction.

In different application examples
- the object 10 can be a metallic object placed in a poorly absorbent medium
- the object 10 can be a dielectric object placed in an absorbent medium
- The object 10 can be a volume of confined liquid placed in a poorly absorbent medium.

REFERENCES [1] Comparison of the seismic and ground probing
radar methods in geological survey by DM

McCann, PD Jackson and PJ Fenning (IEE
Proceedings, volume 135, Pt. F, No. 4, August 1988,
pages 380-390) [2] A magnetometer system to estimate location and
size of long, horizontal ferrous rods by JE

McFee, RO Ellingson, J. Elliott and Y. Das (IEEE
Transactions on Instrumentation and Measurement,
flight. 45, No. 1, February 1996, pages 153-158) [3] Noncontact induced current impedance imaging of
RC Tozer, JC Simpson, IL Freeston and JM

 Mathias (Electronics Letters, April 9, 1992, vol.

 28, no. 8, pages 773-774).

[4] Application of acoustic emission to control
and studying the mechanical behavior of a
unidirectional composite material by P. Gaultier
and B. Paluch (ISMCM) (National Composites Day,
September 9-11, 1986, page 551)

Claims (9)

 1. A method of characterizing a solid or liquid medium, absorbing for electromagnetic waves, characterized in that it comprises the following steps  - emission of an electromagnetic wave (12) towards a surface of a studied volume and scanning of said volume by the electromagnetic wave  - detection on the surface of an acoustic wave (14) and / or a thermal wave originating from said volume studied.  2. Method according to claim 1, which is used for the detection of an object (10) located in this medium, this object (10) having an electromagnetic absorption different from that of the medium (11).  3. Method according to claim 1, in which the electromagnetic wave is focused on the surface of the volume to be observed.  4. Method according to claim 1, in which the electromagnetic wave is modulated.  5. Device for implementing the method according to any one of the preceding claims, which comprises an electromagnetic source (20) radiating in a medium, and at least one acoustic detector (25) coupled to this medium and a scanning system of medium by the electromagnetic beam.  6. Device according to claim 5, which comprises at least one thermal detector (23).  7. Device according to claim 5 comprising a focusing system (21, 22) of the electromagnetic wave (12).  8. Device according to any one of claims 5 to 7 wherein the detectors (23, 25) are synchronized, with a controllable delay, to the amplitude modulated electromagnetic source.  9. Device according to any one of claims 5 to 8, wherein the electromagnetic signal is swept.