FR2828940A1 - OPTICAL FIBER ATHERMIC DEVICE - Google Patents

Abstract

The invention relates to an optical fibre (10) device (100) comprising at least one component which is integrated in the fibre (10) and a support (1) to which the fibre (10) is fixed at two points (50, 52), said points being disposed on either side of the integrated component. The inventive device is characterised in that the support (1) forms a frame and comprises two longitudinal beams (20, 22) which are linked to crossbeams (30, 32) by means of hinges (42, 44, 46, 48). The aforementioned longitudinal beams can slide in relation to one another in the longitudinal direction thereof. Moreover, said support (1) comprises two studs (60, 62) which support the attachment points (50, 52) at the ends of the fibre (10). The inventive device also comprises a compensating element (70) of a pre-determined length having an expansion coefficient that is greater than that of the support (1). During a variation in temperature, said element (70), the ends of which are fixed to one of the beams (20, 22), can cause the beams (20, 22) to slide in relation to one another and the attachment points (50, 52) of the fibre (10) to move in relation to each other.

Description

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OPTICAL FIBER ATHERMIC DEVICE
The present invention relates to the field of optical fibers It relates more particularly to the field of optical fibers comprising an integrated component.

 The present invention applies in particular to fiber optic devices comprising an integrated Bragg grating. In this context, it aims to propose a device for stabilizing the temperature and / or adjusting the Bragg wavelength of the photoinscribed networks in the optical fibers.

 Bragg gratings are periodic structures of the optical index, which have the particularity of reflecting a signal of well-defined wavelength, called the Bragg wavelength of the network. Bragg's network-based systems have already done great service and have given rise to an abundance of literature.

 Optical components incorporating such Bragg gratings are used for example to manufacture chromatic dispersion compensating filters (CDC), gain equalizing filters (FEG), or insertion / extraction multiplexer components (MIE).

 However, it turns out that optical filters provided with an integrated component, in particular a Bragg grating, are sensitive to temperature. In particular, the properties of Bragg grids, and in particular the Bragg wavelength of grids, vary. : - as a function of temperature by thermo-optical effects due to the expansion or compression of the fiber, or to a change in the index of the Bragg grating, - as a function of the traction or of the tension to which it is subjected the Bragg network in fiber.

 It follows that the Bragg wavelength is: - an increasing function of the temperature, and - an increasing function of the traction applied to the fiber.

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 Means are known for limiting the temperature drift of devices using Bragg gratings. The most commonly used means today are known as table-top or half-table-top arrangements. A description of an example of implementation of these means can be found in documents [1] and [2].

 Figures 1 and 2 attached show respectively half table-top and table-top structures according to the state of the art. The half table-top or table-top assemblies consist of a beam 20 made of materials with a low coefficient of expansion such as invar, ceramic, etc. and studs 30 and 32 made of material with a high coefficient of expansion such as aluminum for example. A fiber 10 comprising a Bragg grating is tensioned between the two studs 30 and 32 for the table-top or between the stud 30 and the opposite end of the beam 20 for the case of a half-table -top according to the type of assembly. The fiber attachment points 10 are referenced 12 and 14.

 The distance between these two points 12 and 14 is reduced with increasing temperature, thus the tension applied to the fiber 10 decreases and tends to make decrease the wavelength of Bragg, while the temperature inducing the opposite effect , there is a balance between the two phenomena.

 These arrangements make it possible to compensate for the effects of temperature by assuming at first approximation that the Bragg wavelength is a linear function increasing with temperature and decreasing with mechanical stress exerted on the network. This linear approximation of the compensation remains valid within a certain temperature range.

 A drawback of these assemblies is that, by their design, they have fairly large dimensions. These assemblies have, for example, a length of the order of 45 mm if they are composed of Invar for the beam 20 and aluminum for the studs 30 or 32 This length depends directly on the choice of materials and the ratio between the expansion coefficients of the materials used.

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 At the same time, the evolution of the integration of components in optical networks increasingly requires their miniaturization. Consequently, table-top and half-table-top arrangements appear increasingly bulky.

In addition, the current recommendations in the field of telecommunications impose severe tests of temperature rise and humidity of the components. Consequently, the bonding systems are not sufficient to meet these requirements and, they have been replaced by holding the fiber by brazing on the assembly Most of the time, for reasons of thermo-mechanical incompatibility between the materials having very different coefficients of expansion, these solders are not sufficiently reliable means of fixing. Indeed, this incompatibility induces a very slight but nevertheless harmful slip of the brazed fiber over time on its support
An object of the present invention is to provide an athermal assembly which does not have the aforementioned drawbacks, that is to say an assembly which can reach reduced dimensions and which has good reliability over time.

 To this end, the invention provides a fiber optic device comprising at least one component integrated into the fiber and a support on which the fiber is fixed at two points located on either side of the integrated component, characterized in that the support comprises two parallel longitudinal beams capable of sliding relative to each other in their longitudinal direction and two studs supporting the attachment points of the ends of the fiber, the device further comprising a compensating element of predetermined length having a coefficient of expansion greater than that of the support, positioned substantially parallel to the beams and each end of which is fixed to one of the beams, said element being capable, during a temperature variation, of causing the beams to slide one relative to the 'other and the displacement of the fiber attachment points relative to each other.

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 Such a device has the advantage that the fiber is fixed to the elements of the device having the lowest coefficient of expansion. This characteristic ensures good adhesion of the fixing points when these are made by brazing.

 Compared to the table-top and half-table-top type assembly of FIGS. 1 and 2, the length of the assembly of the invention can be reduced. Indeed, the length of a table-top or half table-top assembly is at least less equal to the length of the fiber to be compensated, plus the length of the compensation pad. In the case of the invention, the factor limiting the size of the device is no longer the length of the different dilating elements but the length of the integrated component. Such devices can therefore reach a length of 25 mm.

 In one implementation of the invention, the support is a support whose longitudinal beams are linked to transverse beams by hinge means.

 The hinges advantageously allow the pivoting of the beams constituting the support with respect to each other and therefore facilitate the sliding of the two longitudinal beams with respect to one another.

 Advantageously, the support can be in one piece.

 The hinge means may consist of thinning of the junctions between the longitudinal and transverse beams.

 Each of the studs can be formed by a protuberance from one of the longitudinal beams, the protrusions being positioned near the opposite ends of the longitudinal beams and facing each other.

 In an implementation of the invention, the compensating element has a general shape of S (it includes a useful part in the form of a beam and two protuberances at the ends of the beam, the protrusions being directed in opposite directions, on the part and

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on the other side of the beam), each end being fixed to one of the parallel beams
The studs being positioned near the opposite ends of the longitudinal beams, the compensating element can be fixed on each beam at its end opposite the end supporting a stud
Other characteristics and advantages of the present invention will emerge from the description which follows which is purely illustrative and not limiting should be read with reference to the appended figures among which: - Figures 1 and 2 already commented schematically represent devices according to the state of the art, - Figure 3 is an example of a device according to the invention, - Figure 4 is a schematic representation of the device when it is in its equilibrium position, - Figure 5 is a representation schematic of the device during a temperature rise, - FIGS. 6 is a schematic representation of the device during a temperature decrease, - FIG. 7 represents the deformation of the structure of FIG. 3 during a temperature rise from +50 C, - Figure 8 shows the deformation of the structure of Figure 3 during a temperature drop of -50 C.

 In FIG. 3, the optical fiber device 100 shown is in the equilibrium position. This fiber optic device 100 comprises a monobloc support 1 in the form of a generally rectangular frame consisting of two longitudinal beams 20 and 22 parallel and of two transverse beams 30 and 32 connecting the ends of the beams 20 and 22 The support has been machined at the junctions between the beams 20, 22, 30 and 32 so as to reduce its thickness at the level of these junctions. These thickness reductions constitute zones 42, 44, 46, 48 of least resistance or hinge which allow the beams 20, 22, 30 and 32 to

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 slightly rotate with respect to each other.

 Each longitudinal beam 20 and 22 comprises near one of its ends a protuberance denoted respectively 60 and 62 The protrusions 60 and 62 of the beams 20 and 22 are each positioned at an opposite end of the support 1. An optical fiber 10 comprising a integrated component is fixed at two points 50 and 52 of the protrusions 60 and 62 so that the integrated component is located between the two fixing points. The fiber optic device further comprises a beam 70 in the general shape of an S (the beam 70 comprises a useful part and two protrusions at its ends, the protrusions being directed in opposite directions, on either side of the beam) each end of which is fixed to one of the beams 20 and 22 at the end opposite to that having a protrusion 50 or 52.

 The beam 70 is made of a material having a coefficient of expansion greater than that of the material constituting the support 1 For example, the beam 70 can be made of aluminum or stainless steel, while the support 1 is made of Invar or Covar.

 FIGS. 4 to 6 schematically illustrate the operation of the device 100 of FIG. 3. We find in these figures the various constituent elements of the device of FIG. 3: the support 1 made up of two longitudinal beams 20 and 22 and transverse 30, 32, the hinges 42, 44, 46, 48 positioned at the junction between the beams 20, 22, 30 and 32, the protrusions 60 and 62 of the beams 20 and 22, the fixing points 50 and 52 of the fiber 10, thus that the S-shaped beam 70, the ends of which are fixed to the beams 20 and 22.

 In FIG. 4, the device 100 is in its equilibrium position. The support forms a perfect rectangle.

 During a rise in temperature, the support 1 and the beam 70 expand, the expansion of the support 1 being less significant than that of the beam 70. The beams 20, 22 and 70 tend to elongate, the elongation of the beam 70 being greater than that of the beams 20 and 22. As illustrated

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 in FIG. 5, the elongation of the beam 70 causes the beam 20 to slide relative to the beam 22 in their longitudinal direction in the direction indicated by the arrows. The support 1 is deformed, this deformation being authorized by the hinges 42, 44, 46 and 48 The support 1 forms a parallelogram. As a result, the fixing points 60 and 62 of the fiber 10 tend to approach, releasing the tension stress of the fiber 10.

 Conversely, during a temperature decrease, the support 1 and the beam 70 contract, the beam 70 contracting more significantly than the beams 20 and 22 of the support 1. As illustrated in FIGS. 6, the beam 70 causes the beams 20 and 22 to slide relative to each other in their longitudinal direction, in the direction indicated by the arrows. The support 1 deforms, this deformation being authorized by the hinges 42, 44, 46 and 48 In the same manner as in FIG. 5, the support 1 forms a parallelogram (inverted with respect to that of FIG. 5). As a result, the fixing points 50 and 52 of the fiber 10 tend to move away, increasing the tensile stress in the fiber 10.

 An assembly is thus produced which reduces the stress in the fiber 10 when the temperature increases and increases this stress when the temperature drops so as to mechanically compensate for the thermo-optical effects of the fiber 10.

 Figures 7 and 8 show the deformation of the support 1 and the beam 70 respectively during a temperature rise of + 500C and during a temperature decrease of -50 C relative to the equilibrium position temperature of the mounting. In these figures, the deformations have been amplified 30 times.

 In such a device, the fiber 10 is fixed on the low expansion material forming the support 1. It is thus possible during its assembly to position the fiber on the support 1 alone and then come to fix the beam 70 In this way, the setting the wavelength of the integrated component to a particular value can be performed a posteriori by shearing the support 1

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 THEN fixing the beam 70.

 In addition, brazing of the fiber on the least expanding material ensures good adhesion thereof. Soldering on a low expansion material ensures better grip in a wide range of temperatures This is due to compression stresses on the fiber present at high and low temperatures. The fiber can also be fixed to the studs by gluing.

 In the above description, the support comprises a one-piece frame. It is of course possible to produce a support comprising beams connected to each other by welds. In this case, the longitudinal and transverse beams can be made of different materials. The materials are chosen to be flexible enough to allow the beams to pivot relative to each other and ensure the hinge effect.

 Note also that in the above description, the studs 60 and 62 are fixed on the longitudinal beams 20 and 22 It is also possible to fix these studs on the transverse beams 30 and 32. In this case, the studs will preferably be located at the opposite ends of the transverse beams 30 and 32 so that the deformation of the support 1 causes the attachment points 50 and 52 located on the studs to move towards or away from each other. The fiber 10 is positioned diagonally with respect to the longitudinal beams 20 and 22 parallel.

 Finally, the compensating element is not necessarily produced in the form of an S-beam such as those shown in the figures. It may for example be a straight beam positioned on bosses produced in an asymmetrical manner on the faces. interior of beams 20 and 22.

 Such an assembly can have a reduction of up to 45% in its length compared to the old assemblies (the longitudinal dimensions can reach 25mm). This reduction in length is indeed limited only

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 by the size of the integrated component.

 Of course, the present invention is not limited to the particular embodiments which have just been described, but extends to any variant in accordance with its spirit.

BIBLIOGRAPHY [1] V. FLEURY Thermal stabilization of Bragg gratings photo-registered on optical fibers, internship report of DESS laser engineering at the University of Sciences and Technologies of Lille.

 [2] J. RIOBLANC et al.

  Optimization of a passive stabilization system for the temperature drift of the tuning wavelength of the Bragg gratings, INOG 96 Paper No 85

Claims (10)

CLAIMS: 1 fiber optic device (100) (10) comprising at least one component integrated into the fiber (10) and a support (1) on which the fiber (10) is fixed at two points (50,52) located on the side and other of the integrated component, characterized in that the support (1) comprises two parallel longitudinal beams (20,22) capable of sliding relative to each other in their longitudinal direction and two studs (60, 62) supporting the fixing points (50,52) of the ends of the fiber (10), the device further comprising a compensating element (70) of predetermined length having a coefficient of expansion greater than that of the support (1), positioned substantially parallel to the beams (20,22) and each end of which is fixed to one of the beams (20; 22), said element (70) being able, during a temperature variation, to cause the sliding of the beams (20; 22) relative to each other and the displacement of the fixing points ( 50,52) of the fiber (10) relative to each other.  2. Device (100) according to claim 1, characterized in that the support (1) is a frame whose longitudinal beams (20,22) are linked to transverse beams (30,32) by hinge means (42, 44, 46, 48).  3. Device (100) according to claim 2, characterized in that the support (1) is in one piece.  4. Device (100) according to one of claims 2 or 3, characterized in that the hinge means (42,44, 46,48) consist of thinning of the junctions between the longitudinal (20,22) and transverse beams (30,32).  5. Device (100) according to claim 2, characterized in that the transverse beams (30,32) are fixed to the longitudinal beams (20,22) by welding and in that the beams are flexible enough to allow them to pivot the relative to each other.  6. Device (100) according to one of the preceding claims, <Desc / Clms Page number 11>  characterized in that each of the studs (60,62) consists of a protuberance from one of the longitudinal beams (20,22), the protrusions being positioned near the opposite ends of the longitudinal beams (20,22) and facing one from the other.  7. Device (100) according to one of the preceding claims, characterized in that the compensating element (70) has a general shape of S, each end of which is fixed to one of the longitudinal beams (20,22).  8. Device (100) according to one of the preceding claims, characterized in that the studs (60,62) being positioned near the opposite ends of the longitudinal beams (20, 22), the compensating element (70) is fixed on each beam (20; 22) at its end opposite the end supporting a stud (60; 62).  9. Device (100) according to one of the preceding claims, characterized in that the support (1) is made of Invar or Covar and the compensating element (70) is made of aluminum or stainless steel.  10. Device (100) according to one of the preceding claims, characterized in that the length of the support is less than 25 mm.