The invention relates to the production of a transition (or pressure crossing) for an optical fiber ribbon for a submarine optical connector.
It is known to be very difficult to seal a transition for an optical fiber ribbon cable at the rear part of an optical connector that can withstand the high pressures in a submarine environment, i.e. at pressures of above 300 bar.
The optical fiber ribbon is coated with a protective sheath which is not watertight at these high pressures.
Moreover, no transition or watertight barrier that can withstand the high pressures in a submarine environment, suitable for optical fiber ribbon connectors is known.
There is therefore a need for a watertight transition able to withstand high pressures for an optical fiber ribbon cable.
The invention provides a method of producing a transition for an optical fiber ribbon for a submarine optical cable, the method comprising the following steps:
This arrangement has the effect of creating a watertight seal for the stripped optical fibers of the ribbon cable, which sealingly and strongly adheres to the silica body of the fibers and to the walls of the through-hole for passage of the cable into the support piece, and optionally to the edges of the through-hole. Such a fiber seal can withstand pressures up to 1600 bar in a marine environment.
The dimensions of the through-hole for the ribbon in the support piece correspond in cross section, preferably to within a small clearance, i.e. to within about 1 mm, to that of the ribbon. This allows the through-hole to be at least partly filled with the adhesive.
The ribbon is passed into the through-hole of the support piece by placing the stripped portion, preferably centered or close to the through-hole of the ribbon, for example by marking one of its ends. This ensures that the adhesive adheres simultaneously to the walls of the through-hole and to the stripped portion of the ribbon.
The ribbon is held in position, in the centered position or close to the through-hole, preferably by means of a tool for holding the cable in position relative to the support piece, for example with a retaining template for holding the cable in place on the support piece (preferably by means of a HT (high temperature) adhesive tape bonded to the cable on either side of the support piece). This ensures that the ribbon is in a stable position relative to the support piece.
Injection of the epoxy adhesive into the transverse hole is preferably carried out, and for safety, until the adhesive protrudes from each side of the through-hole of the support piece.
Advantageously, the adhesive injected into the support piece is polymerised, preferably at a polymerisation temperature above the ambient temperature but below the temperature at which the optical fiber ribbon cable is impaired (for example for one hour at 80° C.). In this way, any creep of the injected adhesive is limited and the polymerisation of the adhesive is accelerated.
Advantageously, the step consisting in mechanically stripping the ribbon over a portion of its length corresponding to that of its passage in the support piece is carried out over a length slightly smaller than that of the through-hole, being set back by at least 1 mm at each end of the through-hole.
The invention also provides a device for producing a transition for an optical fiber ribbon surrounded by a plastic sheath in a support piece of a submarine optical connector, the device comprising:
The mechanical stripping means may for example comprise:
Thus, the optical fiber ribbons may be held trapped in the grooves of the support plate.
The cutting means may comprise a blade designed to be moved along the optical fiber ribbons, preferably in the grooved part of the support plate, parallel to the latter and over a course corresponding to the defined length, away from the means for fastening the ribbons. Thus, the cutting of the ribbons is carried out with the ribbons in tension relative to the fastening means, thereby making it easier for them to be held in place on the support plate.
The blade may be designed to have a cutting section capable of cutting the portion of the sheath placed above the silica optical fiber body, as a thin cut strip.
The fastening means may comprise a system of clamps or the like, these being intended to receive, clamped between it and the support plate, the optical fiber ribbons. This fastening system preferably includes an intermediate pad for protecting the optical fiber ribbons.
This device may comprise in succession from the upstream end to the downstream end in the direction of advance of the blade over the optical fiber ribbons, a clamping assembly, for clamping the optical fiber ribbons, the blade for stripping the ribbons, which is mounted so as to move relative to the support plate for the ribbons, and a retaining bar for holding the ribbons in place.
The invention also provides a transition for a submarine optical connector, defining a through-hole for an optical fiber ribbon surrounded by a plastic sheath, and comprising, in said through-hole:
The invention also provides an optical connector having the aforementioned transition.
One embodiment of the invention will now be described with reference to the appended drawing in which:
The essential steps of the method have been shown schematically in the form of successive blocks.
Firstly, the support piece 5 of the optical connector 7 (not shown) is machined so that it can receive the optical cable 3, therefore providing, in this support piece, a hole 11 of oblong cross section passing through the support piece 5 and intended to receive the cable 3, and more precisely the ribbon 13 consisting of adjacent optical fibers, for example of the MT ferrule type, of the optical cable 3.
The dimensions in cross section of the hole 11 corresponds to within a small clearance, for example to within 1 mm, to the cross section of the optical fiber ribbon 13.
A second, blind hole 15 is formed, this being transversely connected to the first hole (11), approximately in the central region of the latter (cf. also
A first step of the method consists in stripping the cable 3, more precisely the optical fiber ribbon 13, by means of a blade device 19 shown schematically and partially in
This device 19 comprises, in succession from the upstream end to the downstream end in the direction of advance of the blade 21, a set of two opposed clamping bars 23, for clamping the optical fiber ribbons 13, a blade 21 for stripping the ribbons 13, which is able to move relative to a fixed support plate 25 for supporting the ribbons 13, and a retaining bar 27 for holding the ribbons 13 in place while they are being stripped by the blade 21.
One or more optical fiber ribbons 13 are thus placed on the support plate 25, the surface of the latter being grooved so as to accommodate each of these ribbons in parallel grooves 29, the width of which corresponds to that of each ribbon 13. These grooves 29 are parallel to the direction of advance (along the arrow) of the blade 21. The depth of these grooves 29 is defined so that the optical fibers of the ribbon in contact with the support plate 25 protrude from the grooves 29 by at least the thickness of the protective sheath of the fibers plus that of the ribbon, i.e. about 0.1 mm, for conventional optical fibers with a 120 μm diameter for the silica body with a ribbon thickness of 310 μm. The depth of the grooves 29 may thus be about 200 μm, the blade being moved very close to the grooved surface 29 of the support plate 25 and cutting the protruding section of the fiber ribbon (with a thickness of about 310 μm) at the surface of the plate 25.
The ribbons 13 thus positioned, each in one of the grooves 29, are held in position laterally on the support plate 25. These ribbons 13 are also held in position, clamped by means of an intermediate protective pad 31, between the clamping bars 23. This prevents them from sliding under the tensile cutting force for stripping the protective sheath via the blade 21, while the ribbons 13 are being held in position, downstream, by the retaining bar 27 placed against the ribbons 13, in contact with a small area (side clearance) against the latter.
The blade 21 is designed to have a cutting section, for example beveled, capable of cutting that portion of the sheath placed above the silica body of the optical fiber, as a thin cut strip about 100 μm in thickness.
This blade 21 is moved over the ribbons 13, along the arrow, over a length slightly smaller than that of the through-hole 11 of the support piece 5, corresponding to the desired stripping length of the optical fibers of the ribbon 13.
This length of the stripped portion 33 of the optical fibers may be from 1 to several mm smaller than that of the through-hole 11 so that, in the centered position of the stripped portion 33 in the through-hole 11, the stripped portion 33 of each of the fibers, all at the same level transversely to the ribbon, is slightly set back from the edge of the through-hole 11, by half of the aforementioned value.
According to this mechanical stripping method using an upper blade 21, a first strip of the protective sheath of the ribbons 13 is cut without removing it, each of the ribbons 13 treated is turned over and the cut strip rests on the bottom of the groove 29 so as to act as a cutting seat for stripping the portion of the ribbon sheath opposite that already cut. This new cut or second cut strip is opposite the first one (having the same start, the same end and even the same cut depth) and when this second cut has been completed, the first and second cut protective strips are removed. The ribbon 13 is then practically stripped apart from the lateral portions of the optical fibers, which is also easy to remove (by manually cutting it).
Next, the operation of chemically stripping the mechanically stripped ribbon portion 33, shown in the second block diagram at the top towards the right in
Once the chemical stripping operation has been carried out, the stripped portion 33 may be cleaned and degreased, for example using an alcohol-based solvent (not shown). This operation improves the quality of adhesion of the adhesive in the bonding operation described later.
The cable 3 or fiber ribbon 13 is then inserted into the through-hole 11, the position of the stripped portion 33 relative to the through-hole 11 is marked and this stripped portion 33 is held in position relative to the support piece 5. This situation is shown by the third block diagram, toward the right just after the chemical stripping. The centering of the portion 33 in the through-hole 11 may be accomplished by means of a marker reference on the ribbon positioned at a defined distance from the support piece on one side of the latter (not shown).
The stripped portion 33 is held in position relative to the through-hole 11 of the support piece 5 by means of a retaining template 37 (cf. also
Next (see the fourth successive block diagram), the epoxy adhesive 17, which may be a one-component adhesive or a two-component adhesive (with a hardener), is injected into the transverse hole 15 at the through-hole 11. This adhesive 17 is for example injected by a syringe 45 the needle 47 of which (having a length smaller than the depth of the hole 15) is inserted into the hole 15 (
For safety, the injection may continue until the adhesive 17 protrudes from each side of the through-hole 11 at 49, as shown in the present case.
The next step (see the fifth successive block diagram) consists in polymerising the adhesive 17 injected into the through-hole 11, firstly closing off the second hole 15 by means of a plug 51 so as to prevent the adhesive 17 from migrating. This operation is carried out using an oven 53, for example at 80° C. for one hour, in which the support piece 5 with the retaining template 37 for the ribbon 13 is placed (see the fifth successive block diagram).
Once the adhesive has polymerised, the retaining template 37 is removed from the support piece 5 and this support piece 5 or the transition 1 obtained is mounted on the optical fiber 7 as shown in the sixth block diagram of
Such an optical connector 7 has a transition 1 for the cable 3 forming a watertight barrier for connecting the optical cable 3 to the part 9, which can withstand high pressures, up to 1600 bar, and is therefore designed for a sea environment, especially at great depths.
Number | Date | Country | Kind |
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10 56484 | Aug 2010 | FR | national |