SE500915C2 - Splicing appts. for optical fibres - has centrally arranged alignment part with tracks for guiding fibre ends - Google Patents

Abstract

Guides are provided which accommodate the optical fibres (9) and with dimensions matched to the dias. of the optical fibres, so that a fibre can be pushed into them in its longitudinal direction, maintaining an accurately determined alignment. Positioning and retention components hold a fibre in such a position that its ends extend from them to a guide which accommodates them. The components also move the fibre in its longitudinal direction with its end maintained aligned in the guide. A rigid retention part (11,17) is provided in which the fibres are retained aligned with the corresp. guide. Two arms (19) are incorporated each of which with its one end is articulated or bendable in connection with two different places on the retention part (11,17) such as at its ends. Its other end is articulatedly or bendably connected with a rigid fixed under part (15,1).

Description

500 915 2 adapted to accommodate the optical fibers. The guides are dimensioned for the cylindrical shape of the optical fibers and their diameters, so that a fiber can be displaced therein in its longitudinal direction while maintaining a precisely determined orientation. Furthermore, there are means for holding a fiber in such a position that the end thereof projects from the positioning and holding member to a guide for receiving it. These means are further arranged to move the fiber in its longitudinal direction with the end retained aligned in the guide. This retaining means comprises a linking device for moving the retained fiber end. The linking device further comprises in turn - a rigid holding part, in which the fiber is securely held substantially aligned with the corresponding guide, - two arms, - - each with its one end is articulated or flexibly connected to two different places on the holding part, such as at its ends, seen in the longitudinal direction of the fiber held in the holding part, and - - each of which with its other end is hinged or flexibly connected to a rigid, fixedly arranged lower part in the space, - - all the joints being parallel to each other.

The linking device is then of a substantially parallel trapezoidal type, where the arms in the movements of the linking device relevant for the positioning of the fiber end continue to be substantially parallel to each other.

Advantageously, the link device is also of a substantially parallelogram type, ie the opposite links are equally long.

The arms of the linkage device, a portion of the holding part and the lower part are advantageously all or possibly only some of these made of a single piece of material with the joints formed directly by thin flexible material portions. In particular, the whole arms can be thin and flexible.

The plane in which the linking device is movable is of course parallel to the longitudinal direction of the fiber to be held by the holding part, and in particular to the longitudinal direction of the outermost part of the fiber end, which is controlled in the fiber alignment unit.

In a splicing device for two optical fibers there is a positioning device as above for each of the optical fibers, which both positioning devices then have guides for the ends of their optical fibers, which are aligned with each other and are at a small distance from each other. The guides for the ends of the two fibers lie on opposite sides of a cavity, in which electrodes are arranged or can be moved. With electrical voltage across the electrodes, an arc is formed in the usual way for heating the outermost end regions of the fibers and fusing them together.

In a advantageous embodiment, the guides comprise grooves in two upper surfaces of an alignment part, which lie in the same plane.

Grooves are then arranged on both the upper surfaces and a groove on one upper surface is aligned with a groove on the other upper surface, so that these aligned grooves lie on each side of a recess with a depth considerably greater than the depth of the grooves for receiving the electrodes. The movement of the linking device here lies in a plane perpendicular to the upper surfaces.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in connection with the accompanying figures, in which - Fig. 1 shows diagrammatically from the side a device according to the invention, - Fig. 2 shows in perspective obliquely from above a directing part for use in the fiber splicing device, Fig. 3 shows an alternative embodiment of the fiber splicing apparatus of Fig. 3.

DESCRIPTION OF PREFERRED EMBODIMENTS On a lower part or frame 1 a central support 3 is arranged. The support 3 carries on its upper surface a fiber alignment unit 5, which is shown on a larger scale in Fig. 2. The fiber alignment part 5 has carefully aligned grooves 7 on its upper surface, which grooves have a suitable dimensioning for receiving and guiding optical fibers . A plurality of parallel grooves are provided to receive the end of optical fibers arranged as flatband cables, i.e. cables with several optical fibers lying parallel to each other in a single plane and stabilized by an outer plastic casing. The fiber ends which are inserted in the grooves 7 of the fiber alignment unit 5 are generally free from this stabilizing and protective plastic casing and also from any other protective layers, so that only the bare fiber surface is guided by the walls of the grooves 7.

The optical fibers 9 are held in holders 11, which are releasably held on upper surfaces of linking devices 13. The optical fibers 9 are held by the retaining supports 11 at areas of the fiber which are spaced from the bare area at the end of the fiber. The holding supports 11 are further arranged so as to give the fiber a slight inclination in relation to the longitudinal direction of the fiber aligning grooves 7 and to the upper surface of the fiber aligning unit S and they are further located at such a height that with this inclination and this height the fiber ends are pressed down into the grooves 7 and abut and are guided in the grooves, so that the fiber ends here run completely rectilinearly all the way to their end surface. A slight bend of the optical fibers 9 is then obtained between the fiber holders 11 and the alignment unit 5. The bend can of course also be located within an area comprising a smaller part of the fiber alignment grooves 7 at their outer ends.

In the embodiment shown in Fig. 1, the linking device 13 is made of a single material part, such as of a suitable piece of steel. This piece of steel 13 generally has a parallel trapezoidal shape, where in the rest position the two parallel sides are perpendicular to the upper surface of the base part 1. On the upper oblique surface the fiber holders 11 are in place. Furthermore, a substantially rectangular hole is cut in the steel pieces 13 in such a way that these pieces function as a linking device with the upper surface displaceable in an elastic manner relative to the lower surface, attached to the base part 1.

Thus there is a lower part 15 in a piece of steel 13, with a uniform thickness and with such a thickness that this part is completely inflexible. The lower part 15 is suitably attached to the base part or the frame 1. Furthermore, an upper part 17 is formed, which is also completely inflexible and rigid and which on its upper surface supports the fiber holders 11. The upper part is narrower, seen from the side of the device, at its area next to the fiber alignment unit 5. Furthermore, side parts or side arms 19 are formed, which also have a uniform thickness and such a small thickness that they are flexible and function as resilient sheets. When a force is exerted on the upper part 17 of a steel piece 13, a bending of the side arms 19 will take place and this bending is effected mainly in the connection areas between the side arms 19 and the lower and upper parts 15 and 17, respectively. 13 functions as a parallelogram link device, so that when the upper part of the link device is actuated, it is moved or displaced, without changing its angular position, parallel to the upper surface of the base part 1.

By means of this design of the link device 13 as a single steel block with a rectangular cut-out and thin side parts, a double-resilient effect is obtained directly with a rest position, when no force acts on the upper part 17. Furthermore, this link device is completely clear and free movement for the upper part in relation to the lower part.

The movement of the upper parts 17 of the link device 13 is effected by means of a lever device, which for each link device 13 comprises a lever 21, which is pivotable about a joint 23 arranged in a support 25 attached to the base part 1.

The lever 21 has a lever 27, which at its end engages the upper part 17 of a piece of metal 13, and a longer lever 29. The longer lever 29 is actuated at its free end by some fine displacement means, which as shown in the figure may be an ordinary fine-threaded screw 31 guided in a threaded hole in a support 33 fixed to the base part 1. The screw 31 can be provided with a control knob 35 at its second end, which is thus opposite the end which is in engagement with the lever 21. a rotation of the control knob 35, so that the screw 31 is moved further into the support block 33 and thus presses against the lever 29 of the lever 21, the lever 21 will be rotated around its joint 23 and with its second shorter lever 27 act on the upper the part of the linking device 13, which thus entails a movement of this upper part 17 in the direction of the central support 13 and thus in the direction of the place where the two fibers 9 are to meet each other to produce a joint.

When making a joint between two optical fibers 9, these fibers 9 are placed in respective fiber holders 11, which are then attached to the upper surface of the upper part 17 of one of the two link devices 13. The projecting exposed ends of the fibers will be placed in grooves 7. on the fiber alignment unit 5, which grooves are opposite each other. Then, the outermost end region of the fibers is observed by an operator, which is illustrated at 37 in Fig. 1 and which may be assisted to have a lens 39 placed at a suitable distance above the outermost end region of the fibers. To further facilitate viewing, a light source, schematically indicated at 41 may be provided below the outermost end region of the fibers as in a hole 43 in the central support 3. The observer and operator then rotate the control knobs 35 under constant observation of the outermost end region of the fibers until they meet and come into contact with each other with their end surfaces in the middle of the entire splicing device and especially in the middle of the fiber alignment unit 5 and a recess 45 formed therein in the transverse direction. The recess 45 is taken up from the upper surface of the fiber alignment unit 5 and goes in one direction perpendicular to the alignment grooves 7. In order for the light from the lamp 41 to be able to hit the outermost end region of the fibers, it is of course required that either a hole is arranged in a suitable place in the fiber alignment unit 5 and especially through the bottom of its recess 45 in a suitable place - smile. Alternatively, the fiber alignment unit 5 may be wholly or partly made of transparent material.

When the ends of the fibers are placed next to each other and aligned with each other, the ends are connected in a suitable manner such as by means of fusion welding with arc in the conventional manner. For this purpose, two electrodes, indicated at 44 and connected to a suitable voltage source, not shown, are moved in the recess 45 below the end region of the optical fibers and are moved in the transverse direction relative to the longitudinal direction of the fibers. The arc will have a substantially horizontal direction and its upper area will heat the outermost end area of the fibers and fuse them together. Fig. 3 shows a possible embodiment of the splicing apparatus using conventional links. The link device 13 'thus consists here of four rigid link arms, an upper 17', a lower 15 'attached to the base part 1, a side arm 19' arranged next to the central support 3 and a second side arm 19 'arranged at a distance from the central support 3. The different parts of the link device 13 are connected to each other by means of suitable joints and in the neutral position shown in Fig. 3 these link arms thus together form a parallel trapezoid, the two side arms 19 and 19 'of which are parallel and run in a straight line. angle to a lower link 15 ', while the upper link 17' forms a small angle relative to the lower part. In the case of minor movements of the upper part 17 ', the parallelism between the side arms 19' and 19 "will be approximately maintained, while the upper part 17 'can change its angular position slightly, so that the bending angle of an optical fiber 19' when moving the upper part 17 'in the direction of the fiber splicing point itself decreases, which can be advantageous since then the fiber is still retained in its alignment groove 7 without being bent away from it at its side facing the splicing point.

In order to accommodate play in the system and to keep the outer parts of the link device in abutment against the levers 27 of the levers 21, special measures are required, for example that a suitable spring prestress is provided. This can be achieved by means of compression springs 49, which with the first end act on the inner side arms 19 'of the link device 13' and at a second end support against the central central support 3. Alternatively or in addition to these compression springs, tension springs 51 can are arranged acting on the same link arm 19 'and at its other end attach, for example, to the support of the levers 21 in 25.

Furthermore, in the embodiment in Fig. 3, the control knobs 35 in Fig. 1 are replaced by setting motors 53, which, for example, pulse-turn the screw 31 in the thread in the support 33. Suitable pulses can be obtained from operating elements (not shown) in the form of pushbuttons or the like. Furthermore, the outermost end regions of the fibers are considered here in a different way, in that a video camera 55 is arranged in the central hole 43 in the central support 3, which by means of suitable optics depicts the intended fiber splicing area on a monitor, not shown. To illuminate the fiber splicing area, a lamp or light source 57 can furthermore be arranged above the outermost end areas of the fibers and placed on some suitable support (not shown).

The device in Fig. 3 functions in the same way as the device shown in Fig. 1. The operator will here instead consider the fiber splicing area or the outermost end area of the fibers on the screen and operate the actuating motors 53 and thereby the linking device 13 ', so that the end surfaces of the fibers abut at a centered location or generally along the line directly above it. of the electrodes crossed the line.

Claims (16)

9,500,915 PATENT CLAIMS Device for positioning ends of optical fibers (9), characterized by - guides (7) adapted to receive the optical fibers (9) and with dimensions adapted to the diameters of the optical fibers (9), so that a fiber (9) can be displaced therein in its longitudinal direction while maintaining a precisely determined alignment, - positioning and holding means for the fibers (9) arranged to hold a fiber (9) in such a position that the end thereof projects from the positioning and the holding means for a guide (7) for receiving it, and further arranged to move the fiber (9) in its longitudinal direction with the end retained aligned in the guide (7), - the positioning and holding means comprising - - a rigid holding part (11, 17), in which the fiber (9) is securely held substantially aligned with the corresponding guide (7), - - two arms (19), - - - each of which with its one end is articulated or flexibly connected to two different places on the fasth the eel part (11, 17), as at its ends, seen in the longitudinal direction of the fiber (9) held in the holding part, and - - - each of which with its other end is hinged or flexibly connected to a rigid, fixed in the space arranged lower part (15, 1), - - - wherein all the joints are parallel to each other, - - - so that the arms (19) together with the holding part (11, 17) and the lower part (15, 1) form a flat link device of substantially parallel trapezoidal type , where the arms (19) in a movement of the link device are substantially parallel to each other. Device according to claim 1, characterized in that the linking device is of a substantially parallelogram type. Device according to one of Claims 1 to 2, characterized in that at least the arms (19) and a portion (17) of the holding part (11, 17) are made of a single piece of material, which has been given such a shape, that the arms (19) when connected to the portion (17) of the holding part are thin, so that a bending of these connecting areas can be performed, while the portion (17) of the holding part is thick and does not allow any bending. ning. Device according to claim 3, characterized in that also a portion (15) of the lower part (15, 1) is made in the same piece of material and that the arms have been given such a shape that the arms (19) at their area adjacent to the portion (15) of the lower part is thin, so that a bending of these connecting areas can be performed, while the portion (15) of the lower part is thick and does not allow any bending. Device according to one of Claims 1 to 4, characterized in that a plane in which the linking device is movable is parallel to the longitudinal direction of the fiber (9) to be held by the holding part (11, 17). . Device according to one of Claims 1 to 5, characterized in that guides (7) are provided for the ends of two fibers (9) and that a guide (7) for one end of the fiber is aligned with the guide (7) for the other fiber. End. Device according to claim 6, characterized in that the guides (7) for the ends of the two fibers lie on opposite sides of a cavity (45). Device according to one of Claims 1 to 7, characterized in that the guides (7) comprise grooves in the upper surface of an alignment part (5). Device according to claim 8, characterized in that the alignment part (5) comprises two upper surfaces lying in the same plane and that grooves (7) are arranged on both the upper surfaces and a groove (7) on an upper surface is aligned with a groove (7) on the other surface. Device according to claim 9, characterized in that the two upper surfaces lie on opposite sides of a recess (45). 11. ll. Device according to one of Claims 8 to 10, characterized in that the movement of the linking device is in a plane perpendicular to the 1, sno 915 or the upper surfaces. Use of a positioning device according to one of claims 1 to 5 in a splicing device for two optical fibers (9), characterized by a positioning device for each of the optical fibers, which have guides (7) for these optical fibers. fibers, which are aligned with each other. Use according to claim 12, characterized in that the guides (7) for the ends of the two fibers (9) lie on opposite sides of a cavity (45), in which electrodes are arranged or can be moved so that when supplied of suitable electrical energy form an arc for heating the outermost end regions of the fibers (9) and fusing them together. Use according to one of Claims 12 to 13, characterized in that the guides (7) comprise grooves in two upper surfaces of an alignment part (5), which lie in the same plane, and that grooves are arranged on both the upper surfaces. the surfaces and a groove on one upper surface is aligned with a groove on the other upper surface. Use according to claim 14, characterized in that the two upper surfaces lie on opposite sides of a recess (45) with a depth considerably greater than the depth of the grooves (7). Use according to one of Claims 14 to 15, characterized in that the movement of the link device is in a plane perpendicular to the upper surfaces.