FR2629220A1 - Device for assembling and self-aligning an optical fibre with a micro-optical component - Google Patents

Abstract

The device for assembling an optical fibre 12 with a micro-optical component 24 comprises a fibre-carrying cylinder 10 which includes a longitudinal hole 14 receiving the end of the fibre 12, the axis of the hole coinciding with that of the cylinder, and its diameter is slightly greater than that of the fibre, a tubular assembling ferrule (sheath) 20 provided with a longitudinal slit 22, into which ferrule (sheath) the cylinder 10 is fitted, the said micro-optical component 24 also being fitted into the ferrule (sheath) 20.

Description

ASSEMBLY DEVICE AND D1IUTO-ALIGNMENT
OPTICAL FIBER AND HIGROOPTIC ELEHEBT
The present invention relates to a device for assembling and self-aligning an optical fiber and a micro-optical element.

 In fiber optic transmission systems, the fiber ends are mounted in end caps to allow their connection to a wide variety of equipment.

 In this regard, it is known to mount a fiber in a fiber-carrying cylinder comprising a longitudinal hole whose diameter is barely greater than the maximum diameter of the fiber taking into account the production tolerances of the latter, the axis of the longitudinal hole coinciding with the axis of the outer surface of the cylinder, so that when the end of the fiber is received in the longitudinal hole with the interposition of an adhesive, the fiber is rigorously centered in the longitudinal hole and consequently with respect to the outer surface of the fiber-carrying cylinder under the preponderant effect of surface tensions within the liquid adhesive.

 Thanks to such a fiber-carrying cylinder, it is possible to produce a nozzle in which the fiber is rigorously centered.

 For various reasons, various micro-optical elements, such as lenses, are assembled at the end of the fiber.

 The alignment of the fiber axis and the optical axis of the lens, or any other micro-optical element, must be carried out with particular care because all the deviations, transverse, axial or angular, are reflected by unacceptable optical losses at connection.

 In fact, most of the current assembly techniques use optical optimization benches in which a preliminary alignment is carried out by fine adjustment between the fiber and the micro-optical element, then the latter is immobilized in the position desired in relation to the fiber.

These techniques lead to relatively long implementation times and require the availability of an appropriate bench.

Known devices also have other disadvantages
- no repair is possible in case of fiber breakage so that the micro-optical elements are lost
- most are not removable and do not allow access to the end of the fiber for possible cleaning
- they are. consisting of assemblies of parts made of various materials: metals, plastics with very different coefficients of expansion which can induce variations in attenuation as a function of temperature.

 The present invention enables self-alignment between the optical fiber and a micro-optical element, guaranteeing excellent connection performance for example without using an optimization bench and reducing assembly times between the fiber and the 'micro-optical element during the production of the tip.

 According to the invention, the device for assembling the optical fiber and the micro-optical element, of the type. comprising a fiber-carrying cylinder comprising a longitudinal hole whose diameter is hardly greater than the maximum diameter of the fiber taking into account production tolerances -of the latter, said hole being intended to receive the end of the fiber with interposition of an at least temporarily liquid product, the axis of said longitudinal hole coinciding with the axis of the external surface of said cylinder, is characterized in that it comprises an assembly tube whose internal diameter is slightly less than the external diameter of said cylinder , said micro-optical element having at least three outer areas of cylindrical envelope whose axis coincides with its optical axis and whose diameter is slightly greater than the internal diameter of the assembly tube, the assembly tube having at least one longitudinal slot at least partially, 11 micro-optical element being fitted under elastic stress at one end of the assembly tube, and said cyli ndre also being fitted under elastic stress at the other end of the assembly tube.

 Thanks to the invention, a precision self-alignment is carried out between the axes of the fiber and of the micro-optical element without having to resort to an adjustment operation on a bench. Indeed, the fiber being received in a hole with a diameter barely greater than its own diameter will be automatically centered there under the effect of surface tensions of the liquid product interposed between the fiber and the hole; on the other hand, the optical axis of the optical element will be automatically coincident with the axis of the split assembly tube due to its fitting under elastic stress in said tube; Finally, the axis of the fiber-carrying cylinder will also automatically coincide with the axis of the split assembly tube due to its fitting under elastic stress in this tube.

The details and advantages of the invention will become clear on reading the description which follows, with reference to the accompanying drawings, in which
- Figure 1 is a longitudinal sectional view of the assembly device according to the invention
- Figure 2 is a cross-sectional view of the device of Figure 1, taken along line II-II
- Figures 3 to 6 illustrate alternative embodiments
In all these figures, identical or similar elements are designated by the same reference numbers.

 As illustrated in FIG. 1, the device according to the invention firstly comprises a fiber-carrying cylinder 10. This cylinder is preferably made of a material having characteristics close to those of the fiber, in particular coefficient of expansion. As it is a doped glass fiber, it will be advantageous to choose ceramic or glass for the cylinder. As it is a plastic fiber, advantageously a plastic material will also be chosen.

 The cylinder has a longitudinal hole 14 intended to receive the end of the fiber and to keep it as rigorously as possible coaxial with the external surface 16 of the cylinder. For this purpose, the cylinder is manufactured with great precision, by molding or machining, so that its outside diameter is perfectly regular over its entire length.

 The longitudinal hole is drilled with precision rigorously coaxial with the exterior surface of the cylinder. The diameter of this hole is barely greater than the maximum fiber diameter, taking into account the production tolerances of the fiber. For example, in the case of an optical fiber with a nominal diameter of 125 microns, produced with tolerances of + 3 microns, the diameter of the hole will be at most 130 microns.

 As illustrated in FIG. 2, the end of the fiber will thus be received in the hole with a peripheral clearance e of between 1 and 5 microns approximately. This play is kept strictly constant over the entire periphery of the fiber gracie at the interposition of a liquid product 18 between the fiber and the hole. Indeed, given the small thickness of liquid, the forces generated by the surface tension are preponderant and lead to a practically perfect centering of the fiber in its hole.

 By liquid is meant in the context of the invention any liquid or viscous product, at least temporarily. In particular, it may be an adhesive, initially liquid during the establishment of the fiber, which then hardens.

 The assembly device then comprises a tubular sheath 20, also produced with precision, of regular inside diameter and very slightly less than the outside diameter of the fiber-carrying cylinder.

 The sheath 20 is split over its entire length by a slot 22, so that it can receive the cylinder 10 at one of its ends by fitting under elastic stress. This fitting is obtained by progressive penetration of the cylinder into the sheath, the latter opening slightly along the slot in order to compensate for the difference between its own initial internal diameter and the slightly greater external diameter of the cylinder.

 According to a variant not shown, the sheath does not have a slot over its entire length, but one or more partial slots from one and / or the other of its ends.

 Thanks to this arrangement, an almost perfect coincidence is obtained between the axis of the cylinder, and therefore the axis of the fiber as we have just seen, and the interior axis of the sheath 20.

 The sheath 20 receives at its other end a micro-optical element designated under the general reference 24 in the remainder of this description.

 In the embodiment illustrated in FIG. 1, the micro-optical element 24 consists of a bar lens of the plane / convex type having a cylindrical outer surface 26 whose axis coincides strictly with the optical axis of the bar lens by the implementation of high precision production techniques (molding, machining). The diameter of the cylindrical outer surface of the rod lens is also very slightly greater than the internal diameter of the sheath, so that the rod lens is received under elastic fitting in the split sheath, the latter opening slightly along the slot 22 during fitting as has already been seen in relation to the fiber holder cylinder 10.

 Therefore, the optical axis of the rod lens strictly coincides with the inner axis of the sheath and, consequently, with the axis of the fiber, both laterally and angularly.

 It will be understood that the lens may have only three outer areas included in the same radial plane and arranged on a cylindrical envelope, instead of a complete cylindrical outer surface.

 The axial positioning of the end of the fiber with respect to the rod lens is obtained by abutting the fiber holder cylinder against the rod lens, which positions the end of the fiber against the flat face of the lens, located in the focal plane of the lens.

 When it is desired to establish a precise axial positioning of the end of the fiber when the focal plane is situated at a certain distance from the adjacent face of the lens, a calibrated spacer ring, received in the sheath and interposed between the cylinder and lens.

For example, in FIGS. 3 and 4, there are shown spherical and spherical-cylindrical lenses respectively, the focal plane of which is slightly distant from the lens, and the axial positioning of the end of the fiber is obtained by means of a spacer ring. 28, made of a suitable material, ceramic or plastic
According to another variant, the sheath can be of sufficient length to allow the connection of two optical fibers by means of two consecutive lenses, as illustrated in FIG. 5.

 From one end to the other, the split sheath 20 will receive: a first cylinder 10 fiber holder 12, a first lens 24, then symmetrically a second lens 24 'and a second cylinder 10' t fiber holder 12 ', all these components being received in elastic fitting in the sheath as it was said previously.

 In another embodiment, illustrated in FIG. 6, each pair of cylinder + lens 10, 24, 10 ′, 24 ′ will be received separately in a split assembly sleeve 20, 20 ′, then the two assemblies will be introduced into a third connection sleeve 29, also split and with an inside diameter slightly smaller than the outside diameter of the first two sleeves 20, 20 ′.

 In this case, an additional micro-optical element, for example a mirror or an attenuator, may be placed in the third sheath, this element being kept there strictly perpendicular to the common axis of the optical fibers.

In all of the above embodiments, it is possible to juxtapose one of the lenses or to interpose between the two lenses or to substitute for the two lenses a certain number of other micro-optical elements, such as for example
- an attenuation plate,
- a filter,
- a fully reflective, or semi-transparent mirror,
- a polarizer
- an environment. whose refractive index varies as a function of various surrounding parameters temperature, pressure, magnetic, electric or electromagnetic field, etc.

 Such an element has been illustrated with reference 30 to FIGS. 5 and 6.

 It will be noted that the invention provides multiple advantages.

 The precise alignment of the fiber and the associated micro-optical element is obtained by simple and relatively inexpensive accessories and can be carried out by unqualified personnel while guaranteeing excellent optical performance.

 The assembly device is removable, which allows reuse. of certain components in the event of the fiber breaking, or even all of the components in the cases where the fiber is received in its fiber-carrying cylinder surrounded by a product in the permanent liquid state.

The assembly is modular, which allows virtually all possible combinations, using a reduced range of components
- a model of fiber holder cylinder for each standard fiber diameter, all models having the same outside diameter, and longitudinal holes of diameters adapted to each standard fiber diameter;
- a unique model of split assembly sheath, if necessary available in various lengths
- an assortment of micro-optical elements all having an identical outside diameter, which can therefore be fitted on demand into the sheath according to the intended application
- if necessary, a second model of connection sleeve as it has been seen in relation to FIG. 7.

 For mounting on a mechanical support assembly of a tip or optical point, made according to the invention of the fiber-carrying cylinder, - of the split assembly sheath and of the micro-optical element, a mounting sleeve will also be provided. 32, or reference body, comprising a cylindrical housing 34 receiving the rear end of the fiber-carrying cylinder 10, and provided with positioning surfaces relative to the support.

 As illustrated in FIG. 1, it may be an external cylindrical surface 36, coaxial with the cylindrical housing, and a flat front surface 38 perpendicular to this axis.

 As illustrated in FIG. 3, it could be a pair of cylindrical surfaces 36 and 37 spaced apart longitudinally and a rear abutment surface 38.

Claims (8)

1. Device for assembling and self-aligning an optical fiber (12) and a micro-optical element (24), of the type comprising: a fiber-carrying cylinder (10) having a longitudinal hole (14 ) intended to receive the end of the optical fiber (12) with the interposition of a product (18) at least temporarily liquid, the axis of the hole precisely coinciding with that of the outer surface (16) of the cylinder and its diameter being slightly greater than the maximum diameter of the fiber, characterized in that it comprises a tubular assembly sheath (20), the internal diameter of which is slightly less than the external diameter of the cylinder, provided with at least one longitudinal slot at least partial (22), said cylinder (10) being fitted under elastic stress at one of the ends of the assembly sleeve (20), and said micro-optical element (24) having at least three outer ranges of cylindrical envelope ( 26) whose axis coincides with its optical axis and whose diam It is slightly greater than the inside diameter of the sheath, said micro-optical element (24) also being fitted under elastic stress at the other end of the sheath (20). 2. An assembly device according to claim 1, characterized in that said product (18) at least temporarily liquid consists of an adhesive. 3. An assembly device according to either of claims 1 and 2, intended for an optical fiber (12) in doped glass, characterized in that the cylinder (10) and the sheath (20) are made of ceramic or glass. 4. An assembly device according to either of claims 1 and 2, intended for an optical fiber (12) made of plastic, characterized in that the cylinder (10) and the sheath (20) are made of plastic material. 5. An assembly device according to any one of claims 1 to 4, characterized in that the longitudinal hole (14) of the fiber holder cylinder has an inner diameter greater by a few microns than that of the outer diameter of the fiber. 6. An assembly device according to any one of claims 1 to 5, characterized in that it comprises a spacer ring (28) received in said assembly sleeve (20) and intended to establish a predetermined axial distance between the fiber holder cylinder (10) and the micro-optical element (24). 7. An assembly device according to any one of claims 1 to 6, characterized in that it also comprises a tubular connection sheath (29), provided with a longitudinal slot, whose internal diameter is slightly less than the diameter outside of the assembly sleeve (20) and intended to receive in elastic fitting at least one assembly consisting of a cylinder (10), an assembly sleeve (20) and a micro-optical element (24) . 8 An assembly device according to any one of claims 1 to 7, characterized in that it comprises a reference body (32) provided with a cylindrical housing (34) intended to receive at least part of the cylinder (10 ) fiber holder, and provided with reference surfaces (36, 37, 38) intended for its positioning with respect to a device to which the fiber is to be connected.