FR2678392A1 - Low-cost method for splicing optical fibres - Google Patents

Abstract

The present invention relates to a method for splicing optical fibres, characterised in that it comprises the steps consisting: i) in inserting (threading) the respective ends of two fibres (1, 2) to be connected into a heat-shrinkable capillary sleeve; ii) in placing the capillary sleeve (10) in a split ring (20) made of electrically conducting material; and iii) in connecting the ends (21, 22) of the split ring (20) to an electrical power supply (30) in order to heat the split ring (20) and the capillary sleeve (10) so as to grip the latter tightly over the ends of the optical fibres by releasing the surface tensions in the capillary.

Description

 The present invention relates to a method and a device for splicing optical fibers.

 Different methods and devices for splicing optical fibers have already been proposed. These give more or less satisfaction.

 The present invention now aims to provide a new method and a new device which allow reliable splicing of optical fibers, at low cost.

 This object is achieved according to the present invention by a method which comprises the steps consisting in i) threading the respective ends of two fibers to be connected into a capillary sleeve capable of thermal shrinkage, ii) placing the capillary sleeve in a split ring of material electrically conductive, and iii) connect the ends of the split ring to an electrical power source to heat the split ring and the capillary sleeve in order to tighten the latter on the ends of the optical fibers by releasing surface tensions in the capillary.

 The splicing device according to the present invention comprises - a capillary sleeve made of material capable of thermal shrinkage, capable of receiving the ends of the optical fibers to be connected, - a split ring made of electrically conductive material, and - a source of electrical power able to be connected to the ends of the split ring.

 According to an advantageous characteristic of the present invention, the capillary sleeve is made of glass.

 Other characteristics, objects and advantages of the present invention will appear on reading the detailed description which follows and with reference to the appended drawings given by way of nonlimiting example and in which - Figure 1 represents a schematic perspective view of a splicing device according to the present invention, - Figure 2 shows a schematic view in longitudinal section of a glass sleeve according to the present invention after shrinking on the ends of optical fibers, and - Figure 3 shows a schematic view in longitudinal section of the glass sleeve with the use of an index adapter ball, with a low melting point.

 The splicing device according to the present invention shown in the appended FIG. 1 is designed for the connection of the ends of two optical fibers 1 and 2.

 This splicing device essentially comprises - a glass capillary sleeve 10 capable of receiving the ends of the optical fibers 1 and 2 to be connected, - a split ring 20 made of electrically conductive material, - a power supply source 30, - a switch 40 designed to connect the electrical power source 30 to the ends 21, 22 of the split ring 20 and, - an enclosure 50.

 The sleeve 10 has a straight cylindrical and through central channel 12 adapted to receive the ends of the optical fibers I and 2 to be connected.

 Preferably, this channel 12 has a constant diameter over its length. This diameter is greater, while being substantially complementary, to the external diameter of the fibers 1, 2.

 Preferably, there is provided a set of glass capillaries 10 having central channels 12 of constant diameter for the same sleeve, but different from one sleeve to another, in order to connect different types of optical fibers 1, 2 .

 Furthermore, if necessary, glass capillary sleeves 10 can be provided, having a channel 12 formed by two coaxial portions each covering substantially half the length of the sleeve 10 and having diameters different from one portion to the other for connect optical fibers of different diameters to each other, while ensuring self-centering of these fibers.

 The ring 20 has a slot 23 as indicated above. The width of this slot 23, that is to say the distance between the ends 21, 22 of the ring 20, is at least equal to the diameter of the optical fibers 1, 2, in order to allow the withdrawal of the ring 20 after completion of the splice.

 The ring 20 is preferably made of graphite. Its electrical resistance measured between the ends 21, 22 is preferably of the order of 0.1 ohm.

 The electric power source 30 connected to the ends 21, 22 of the ring 20 via the switch 40 can be formed of any suitable known structure. Preferably, it is an electric battery in direct voltage, typically a 12 Volt battery.

 The internal diameter of the ring 20 must be greater than the external diameter of the sleeve 10 in order to allow easy removal of the ring 20. However, the internal diameter of the split ring 20 is substantially complementary to the external diameter of the capillary sleeve. glass 10 to allow good heat exchange between these two elements, when the ring 20 is heated by the Joule effect thanks to the electric power source 30.

 The enclosure 50 is designed to accommodate the ring 20 threaded on the sleeve 10 receiving the ends of the two optical fibers 1, 2. Preferably, the power supply source 30 is housed outside the enclosure 50. However, provision can be made for the enclosure 50 to also receive this source 30.

 The enclosure 50 can be formed of numerous variants. It preferably comprises sealed passages for crossing the optical fibers 1, 2 and the connecting wires connected to the electric power source 30.

 The sealed enclosure 50 is designed to define a controlled atmosphere around the ring 20 and the glass capillary sleeve 10.

This controlled atmosphere can be formed of a neutral gas, typically argon, or even of a partial vacuum, to avoid combustion of the graphite ring 20.

 For this, the enclosure 50 is provided with a tube 52 designed to be connected either to a source of supply of neutral gas, for example argon, or to a primary pump.

 According to a preferred characteristic of the present invention, the splicing device also comprises means capable of driving the mandrel 10 in alternating rotation over more or less one revolution.

These drive means have not been shown in Figure 1 attached to simplify the illustration. They may be formed from any suitable conventional structure known to those skilled in the art.

 The purpose of the alternating rotation drive of the mandrel 10 is to prevent it from buckling, despite its softening.

 It also guarantees uniform heating of the mandrel 10.

 We will now describe the splicing process according to the present invention.

 The two optical fibers 1, 2 to be connected are first stripped at the end and cleaved. They are then threaded into the channel 12 of the glass capillary 10, the cleaved end faces of the fibers 1, 2 being maintained under slight pressure, for example by simple buckling.

 The glass capillary 10 is then placed in the graphite ring 20, the capillary being held by a mandrel capable of operating an alternating rotation as indicated above.

 The assembly thus formed is enclosed in the sealed enclosure 50 into which either a neutral gas (argon) is introduced, or a partial vacuum is created.

 The capillary support mandrel 10 is set in oscillation and the switch 40 is closed. The graphite susceptor 20, the resistance of which is of the order of 0.1 ohm, is brought to a temperature of the order of 1500 "C in less than a second. The surface tensions released in the glass capillary 10 , tighten it on itself and in a few seconds the two optical fibers 1, 2 are held by the sleeve 10.

The switch 40 can then be opened and the connection of the two fibers 1, 2 thus formed, can be tested by measuring the optical attenuation.

 Note that a 12 Volt battery with a power of 380A / H allows 10,000 splicing processes or repetitive tests, if the heating time is approximately 1 second.

 If the test performed is satisfactory, the assembly can then be immersed in a resin to permanently freeze the connection point.

 It is preferably a polymerizable ultraviolet resin. This removes any mechanically fragile point at the outlet of the capillary 10.

 There is shown in FIG. 2, in longitudinal section, a glass sleeve 10 constricted on the ends of the two optical fibers 1, 2.

 There is also shown schematically in Figure 3, the possibility of inserting into the glass capillary sleeve 10, between the ends of the two optical fibers 1, 2 to be connected, a mass of index adapter material, for example a ball 60 at a low melting point, so that this mass 60 coats the ends of the optical fibers 1, 2, after heating by the split ring 20.

 Of course the present invention is not limited to the particular embodiment which has just been described but extends to all variants in accordance with its spirit.

 The glass is used to produce the mandrel 10, given its fairly low softening temperature and for its good mechanical strength. It can however be replaced for any equivalent material.

Claims (22)

 1. A method of splicing optical fibers, characterized in that it comprises the steps consisting in i) threading the respective ends of two fibers (1, 2) to be connected into a capillary sleeve capable of thermal shrinkage, ii) placing the capillary sleeve (10) in a split ring (20) of electrically conductive material, and iii) connecting the ends (21, 22) of the split ring (20) to an electrical power source (30) to heat the split ring (20) and the capillary sleeve (10) in order to tighten the latter on the ends of the optical fibers by releasing surface tensions in the capillary.  2. Method according to claim 1, characterized in that the capillary sleeve (10) is made of glass.  3. Method according to one of claims 1 or 2, characterized in that it comprises the prior step of stripping and cleaving the ends of the optical fibers to be connected.  4. Method according to one of claims 1 to 3, characterized in that the split ring (20) is gaphite.  5. Method according to one of claims 1 to 4, characterized in that it further comprises the step of driving the capillary sleeve (10) in alternating rotation during the feeding of the split ring (20 ) by the electrical power source (30).  6. Method according to one of claims 1 to 5, characterized in that it comprises the step of placing the assembly comprising the capillary sleeve receiving the ends of optical fibers and the split ring engaged on the sleeve in a sealed enclosure under controlled atmosphere during the supply of the split ring (20) using the power supply (30).  7. Method according to claim 6, characterized in that the sealed enclosure (50) contains a neutral gas such as argon.  8. Method according to claim 6, characterized in that the sealed enclosure (50) is evacuated at least partially during the supply of the split ring (20) using the power supply ( 30).  9 Method according to one of claims 1 to 8, characterized in that it comprises a step of embedding the capillary sleeve (10) receiving the ends of the optical fibers (1, 2) in a resin.  10. Method according to one of claims 1 to 9, characterized in that it comprises the additional step of placing an index adapter material (60) with low melting point between the ends of the optical fibers (1 , 2) to be connected before the split ring (20) heats up.  11. Device for implementing the method according to one of claims 1 to 10, characterized in that it comprises - a capillary sleeve (10) made of material capable of thermal shrinkage, capable of receiving the ends of the fibers optics to be connected, - a split ring (20) of electrically conductive material, and - an electrical power source (30) capable of being connected to the ends of the split ring (20).  12. Device according to claim 11, characterized in that the capillary sleeve (10) is made of glass.  13. Device according to one of claims 11 or 12, characterized in that the split ring (20) is made of graphite.  14. Device according to one of claims 1 1 to 13, characterized in that the split ring (20) has an electrical resistance of the order of 0.1 ohm.  15. Device according to one of claims 11 to 14, characterized in that the width of the slot (23) of the split ring (20) is greater than the diameter of the optical fibers (1, 2) to be connected.  16. Device according to one of claims 11 to 15, characterized in that it comprises means capable of driving the sleeve (10) in alternating rotation during the electrical supply of the split ring (20).  17. Device according to one of claims 11 to 16, characterized in that it further comprises a sealed enclosure (50) in a controlled atmosphere capable of receiving the assembly formed of the split ring (20) threaded on the capillary sleeve (10).  18. Device according to claim 17, characterized in that the enclosure is connected to means for supplying neutral gas such as argon.  19. Device according to claim 17, characterized in that the enclosure is connected to a pump.  20. Device according to one of claims 11 to 19, characterized in that it further comprises a resin capable of coating the sleeve (10) constricted on the ends of the optical fibers (1, 2).  21. Device according to one of claims 11 to 20, characterized in that it comprises a mass of index adapter material capable of being placed in the capillary channel (10) between the ends of the optical fibers (1, 2) to be connected.  22. Device according to one of claims il to 21, characterized in that the electric power source (30) is formed by a battery in direct voltage.