FR2620218A1 - Method for measuring a magnitude associated with a strain deformation using optical fibres - Google Patents

Abstract

The invention relates to a method for measuring a magnitude associated with a strain deformation using optical fibres, which consists of a polarisation-preserving optical fibre placed in a curable material when it is in its liquid phase in a zone to be studied or monitored. A light source of linear, given and constant polarisation emits a light signal into the optical fibre. When the optical fibre is stressed, a modification of the crystal structure of the optical fibre is produced, whence the modification of the polarisation. At the output of the optical fibre, adjustment means make it possible to send the light signal onto detectors. Since the intensity of light received on the detectors for a given fixed adjustment, and the same initial polarisation, are known the measurement of the intensity received makes it possible to determine the modification in polarisation, and therefore the modification in strain.

Description

 The present invention relates to a method for measuring deformation in a material using optical fiber as a measurement sensor and as an optical transducer.

 One of the aims of the device is to transmit remotely by purely optical means, information relating to the state of a material coming from an area to be monitored or studied. There are two mechanical methods for measuring a quantity associated with a stress.

 The first, known as an electric extensiometer by strain gauge, consists of a constantan wire, glued in a zig-zag on a very thin support. This is then glued to the structure in a judiciously chosen location. When such is deformed, the wires of the gauge lengthen by an amount d1, in the axis of the gauge and its resistance varies as a function of the elongation d1. By connecting the gauge to a weatstone bridge, the variation in resistance is thus measured. The value of the deformation is then deduced therefrom.

 This process has the major drawback of being unable to inform the user about the variations in deformation inside the material, of being sensitive to external aggressive agents (electromagnetism, alkaline salts.) And of having a duration very limited life.

 The second process is known as a vibrating string product. A rope placed on the structure to be studied is vibrated with a given wavelength and frequency. When a deformation of the structure occurs, the wavelength of the vibration maintained in the string varies. There is therefore a modification in the frequency of the oscillations which makes it possible to deduce a measurement of a variation in deformation.

 Furthermore, the use of optical means has already been envisaged for carrying out such measurements.

 Some use optical fiber as a means of transporting information, but the detection means remains mechanical and therefore sensitive to parasites.

 Others use optical fibers placed inside the material but analyze other phenomena such as light losses, color differences, measuring the amount of light as well as measuring the interference produced between several fibers or inside a fiber meme.

One of the aims of the present invention is to overcome the drawbacks which have just been described while transmitting information originating from the core of the material and remaining insensitive to disturbances of all kinds.
This process applies especially to "hardenable" materials, ie those which, during their manufacture or their installation pass through one. liquid phase and which then solidify C plastic, based on hydraulic binder, composite material. This is to place the fiber inside the material to measure a quantity associated with a stress in said material. It is always possible to place a fiber on the surface to measure deformations on the material but one loses one of the important advantages of this method than being able to analyze the core of the material.

 During the phase. liquid of the hardenable material, an optical fiber is passed by positioning it in the zone where one wants to make measurements. Once the material is in place, a polarized light signal is sent into the fiber. The polarization of the light signal leaving the optical fiber is measured by comparing the light intensity received on the reception means with respect to a known light intensity for a p la r i sat i on of.

 The modification of the polarization is obtained by a purely optical effect called birefringence.

For this, the measuring device according to the invention comprises
- A light source.

 - Means polarizing the light emitted by said source if it is not already.

- Modulating means in order to obtain a signal
Bright "clean".

 - Means intended to converge the light rays emitted by said source on means for positioning and adjusting the optical fiber relative to the optical means used.

 - One (or more) optical fiber (s).

- Optical means intended to make the light signal coming from the end of the fiber converge on receiving means
- Means for receiving the light signal preceded, if necessary, by means of polarization and adjustment to obtain a maximum of light thereon.

 - Detection means to eliminate light noises and obtain a signal that can be analyzed.

 - Analysis means for determining the variation in polarization of the light output signal for the same polarization of the source signal.

 This method makes it possible to implement several embodiments.

 The embodiments depend on the type of optical fiber to be used and on the type of measurement to be carried out, global or specific.

 In a first embodiment, for a polarization and for any fiber, the light is polarized input and leaves the polarized optical fiber. It is advisable to place two detection means preceded by two crossed polarizers so as to obtain the two components of this polarization.

 A second embodiment is characterized by a fiber which maintains polarization and a rectilinear polarization. This embodiment is preferable because the polarization is easier to study.

 Preferably, the light signal is transmitted in the optical fiber as "cleanly" as possible. For this, it is necessary to set up modulating and analytical means.

 As a variant or in addition, it would be preferable to use the means of optoelectronics in order to obtain a simpler and more precise assembly allowing an easier practical application.

Other characteristics and advantages of the invention will appear on reading the detailed description below, made with reference to the appended drawings in which:
Figures la and 1b show the fundamental principle of the invention.

 FIG. 2 represents an embodiment of the invention in the case of any polarization.

 FIG. 3a represents a second embodiment for the preferable case where the polarization is rectilinear and the fiber maintains polarization.

 Figure 3b shows a variant of the previous embodiment where the optical system used has made it possible to simplify assembly.

 @ Figure 4 shows another embodiment.

 FIG. 5 represents another aspect of the invention for the case of point measurements.

 FIG. 6 represents the signals received by the detectors during a compression test as a function of time.

 @ Figure 7 shows the signals of Figure 6 once analyzed, depending on the effort undergone by the optical fiber or the material in which it is placed.

 Although the stress-strain measurements will be described, the invention is applicable in many fields after adaptation.

 Indeed, the principle of the invention is to use the property that the optical fiber has of being a birefringent material because it is composed of silica. When the optical fiber undergoes a physical effect (stress, deformation, pressure, tension) there is a modification of the crystal structure of the fiber. When a polarized wave will encounter this change in structure ~ and by birefringence effect, there is modification of the initial polarization. The method makes it possible to highlight a stress variation as a function of the variation of the polarization.

 The polarization is known by measuring the light intensity received on reception means.

This received light intensity is compared to a known intensity corresponding to a given polarization, adjusted with a fixed polarizer, these two intensities are obtained with the same polarization of the source signal.
FIGS. 1a and 1b schematically represent the effect produced on the polarization of the light passing through the optical fiber when the latter undergoes a force. Under the effect of a force F, the polarization of the light leaving the optical fiber performs a rotation. When the optical fiber is not loaded (Figure la), the polarization is at an angle α; @
If the optical fiber is loaded, the polarization "turns" and takes the value ss (figure 1b). As a function of the angular variation, the polarization, there is deduced therefrom a variation or a measurement of a quantity associated with a stress-deformation.

FIG. 2 shows the measuring device implementing the method of the invention.

 A light source (100) emits a light ray towards the end of the optical fiber. It passes through a polarization means (101) and through optical and adjustment means (102) which make this light ray enter the fiber (103) directly.

 Previously, it passes through modulating means (140) which will "purify" the light signal to let only pass the signal from the light source (100) of the assembly. The optical fiber is previously placed in the material to be studied and fixed at the ends by positioning elements (105).

 At the other end of the optical fiber, the light signal is recovered by other optical and adjustment means (110) and then in an optical divider (120). The two signals thus formed are directed to two polarization means. (121 and 122) which are crossed between them. The two light signals are picked up by two detection means (126) which convert the light rays into electrical signals. These light signals are sent into an analysis means (160) itself connected to the modulator means (150) which synchronizes the signals (that of modulation and the two received signals).

 To obtain a measurement of deformation, it is necessary to adjust a polarization means (121) in such a way that a maximum of light signal is allowed to pass over one of the detection means and that the other (122) is adjusted perpendicularly to the element 121. The polarization means (101) only serves to obtain polarized light at the entrance to the optical fiber (103). The settings for the polarizers should no longer be changed.

 When a stress is exerted on the fiber or on the material in which it is found, the polarization performs a rotation. At the output of the optical fiber (103), the intensity of the light signals picked up by the detection means (126) is modified. We can therefore measure a change in poarization by analysis of changes in intensity received by comparing it to that obtained when we have adjusted the polarization means (121). We can therefore measure a variation in stress-strain.

 C: diagram is a schematic diagram, it has been implemented with single-mode fibers and any polarization.

 From this basic assembly, it is possible to find many variants which can simplify the assembly or measure other types of quantity.

 Figure 3a shows the basic principle of Figure 2, but the fiber z (103) is replaced by a polarization maintaining fiber (203), which simplifies the assembly and the measurements and which made it possible to obtain the results in Figure 6.

 In this case, there is only to study the component of the polarization because this one is. straight. This eliminates the divider cube (120), a polarization means t 122) and a reception means (126) hence a simplification of assembly for the same result.

 Figure 3b shows an even more simplified system by the use of opto-electronic means and the use of connection means. By this variant, the system is no longer sensitive to light noises> ::, because the light signal emitted by the light source (100) is never in contact with the external medium between it and the adjustment means (105) as well as between elements 105 and 126.

 The elements 100, 101 and 10.2 can be replaced by the opto-electronic means (200) connected to the optical fiber by connection means (205) replacing the positioning means (105). It is the same for elements 110, 121 and 126 replaced by an opto-electronic element (210).

 The polarized light signal is emitted by opto-electronic means (200), which are connected to the optical fiber (203) placed in the material to be studied, by the connection element (205) At the other end of the optical fiber, reception means (210) connected to analysis means (160) making it possible to determine the variation in polarization.

 By this same method, one can measure the stress exerted on the optical fiber or in the material in which it is placed.

 This operating mode adapts very well to a practical application by its simplicity and the elements that it implements.

 A variant of this operating mode, represented by FIG. 4, could be the addition of a divider cube (120) between the opto-electronic means (200) and the adjustment means (105).

One of the light signals goes to a receiving means (126) and the other would pass through the optical fiber (203).

 A last variant is represented by FIG. 5. In this embodiment, it is no longer a question of analyzing the light which passes through the optical fiber but that which returns on itself after having encountered a modification of the crystal structure of the optical fiber (203) created by a stress acting on the fiber or in the material in which it is positioned.

 The device consists of a light source (100), a polarization means (101) and optical and adjustment means (102). One can also put an opto-electronic means (200). We then have a divider cube (120). The light signal emitted by the light source ((100) passes through these various elements and enters the optical fiber (203) placed in the material to be studied. The stresses create in the fiber a modification of the crystal structure. a small part of the light signal emitted takes the opposite path from the direction of initial propagation. Back to the divider cube (120), it is oriented towards a detection means (126) preceded by polarization means (121).

 As with the other operating modes, the analysis of the signals is identical.

 In addition, by measuring the time taken between the emission and the reception of the light signal on the reception means and by knowing the wavelength and the speed of propagation of the light by the optical fiber, it is possible to determine the distance traveled. by the light signal: .--- :. One then determines the precise point of the change in crystal structure, therefore that of the stress modification.

 FIG. 6 schematically represents the signals obtained with the device of FIG. 3a. It shows the variation in light intensity I received by the receiving element (126) as a function of time during a loading test on a test tube in which the fiber transmitting the light signal was placed. The polarization means (121) is adjusted so that the light intensity Io re @ ue when the test piece is not loaded, is maximum (point A). This setting should not be changed any more.

 During loading, there is a decrease in the light intensity received to go through zero (point B). The detection means (121) no longer receives light, the polarization has therefore rotated 90 relative to the initial polarization the set on the polarizer t (121) because the light no longer passes when the two polarizations are crossed (perpendicular between they). Continuing the test, we see that the light intensity passes through a maximum in the negative values (point C) which corresponds to a rotation of the polarization of 180. We can, similarly, say that the polarization has rotated 270C at point O.

 FIG. 7 translates the short shown in FIG. 6 n plotting the light intensity I as a function of the force F applied to the test piece during this same compression test described in FIG. 6. There is a sinusoidal shape of the curve obtained which translates a certain relationship between the loading and the rotation of the polarization of the light signal passing through the fiber passed through the test piece.

Claims (9)

 1. Method for measuring a quantity associated with a stress-deformation undergone by a hardenable material characterized in that said material being hardened is passed through by at least one optical fiber in the (or) zone (s) of the material in which we want to measure said quantity  - We send a light polarized by one end of each of the optical fibers;  - The polarization of the light exiting through its other end is measured for each pique fiber; and  - From the difference of the polarizations received, for the same polarization of the source signal, we deduce therefrom, using analysis means (160), the quantity sought at a given instant.  2. Method according to claim 1 characterized in that one carries out measurements in material which during their establishment, their manufacture or because of their physical or chemical nature passes from a liquid state to a solid state which allows the fiber to be placed in the material.  3. Method according to claims 1 and 2 characterized in that one uses, preferably any other, an optical fiber with polarization maintenance.  4. Device for measuring a quantity associated with a stress-strain undergone by a hardenable material, characterized in that it comprises:  - a light source (100)  - polarization means (101) of the light emitted by said source  - at least one optical fiber (203) of sufficient length to pass through the material in the measurement area  - polarizing means (121) of the light signal leaving the (or) fibers.  - Receiving means (126) of the light signal to receive the polarized light signal.  - analysis means (160) for determining the variation in polarization of the output light signal for the same polarization of the source signal.  5. Device according to claim 4, characterized in that modulating means (140 and 150) placed between the polarizing means (101) and the optical fiber (103) making it possible to obtain a light signal which can be used for measurements.  6. Device according to @evendication 4 characterized in that optical means (102) intended to converge the light signal in the optical fiber (103).  7. Device according to claim b characterized in that it consists of positioning and adjustment means (105) of the optical fiber relative to the optical means used.  8. Device according to claims 1, 6 and 7 characterized in that opto-electronic means (200,205,210) can be used to simplify assembly.  9. Device according to claims 1 and 4 characterized in that an analysis of the polarization of the return light signal by the addition of a divider cube (120) between the elements 102 and 105 makes it possible to determine said quantity in a manner punctual.