CA1213424A - Mirror mechanism for fusion-splicing apparatus - Google Patents

Abstract

MIRROR MECHANISM FOR FUSION-SPLICING APPARATUS

Abstract of the Disclosure Apparatus for fusion-splicing two optical fibers, comprises a pair of supports each arranged to support one of said fibers in end-to-end relationship to the other fiber such that the juxtaposed ends of said fibers are juxtaposed in a predetermined region between said supports. Electrode means for generating a spark discharge in said region for heating the end portions of fibers inserted therein, conveniently comprises a pair of electrodes disposed one each side of the alignment axis for the fibers.
Alignment of the fibers is monitored by viewing them with the aid of mirror means having a mirror surface inclined relative to a common plane of the alignment axis for the fibers and a predetermined viewing direction. The mirror surface provides an image corresponding to a view of said fibers taken in a direction transverse to said viewing direction. Spattering of the mirror during the heating process is avoided by displacing said mirror means in said viewing direction between a first position close to said alignment axis, wherein said mirror means can provide said image, and a second position further away from said alignment and the viewpoint.
Because the mirror is not displaced sideways, i.e. along the alignment axis, the fibers can be gripped very close to their ends to minimize flexing which can arise due to surface tension effects and cause realignment of the fibers during the fusion step.

-(i)-

Description

lo The invention relates to apparatus for fusion-splicing optical fibers, and especially to a mirror mechanism therefore The invention is especially concerned with such apparatus which comprises two supports, for example Vie grooves, to which the fibers are clamped so that they are aligned end-to-end.
One of the supports is movable transversely of the longitudinal axis of the fibers to facilitate accurate alignment of the fibers.
Electrodes are arranged to provide a spark discharge in a zone encompassing the juxtaposed ends of the two fibers. The spark discharge heats the end portions of the fibers until they are soft enough to fuse, whereupon they are urged together longitudinally to cause them to fuse together.
During the alignment procedure, it is desirable to view the fibers from more than one direction, preferably mutually perpendicular, to ensure correct alignment in all planes through the longitudinal axis. In known apparatus, the desired views in two mutually perpendicular directions are provided by a Vie mirror positioned behind the fibers with its apex parallel to the longitudinal axis. The surfaces of the mirror are so inclined as to reflect views from both sides of the fibers towards the viewer, for example parallel to the optical axis of the microscope, where applicable. To ensure that the mirror is not spattered during the heating step, it is repositioned to one side of the optical or viewing axis after the alignment has been effected.

I, 'I

' 31 2~3~
A disadvantage of this apparatus is that one of the fibers is unsupported for the relatively large distance needed to accommodate the mirror during the heating step Consequently the unsupported end portion of the fiber can flex during the heating step, which may result in misalignment. This is particularly likely when fusion-splicing single mode optical fibers. The cores of the single mode fibers are only about 10 microns diameter (or even less) and must be aligned very precisely. The required precision cannot necessarily be achieved by aligning the exteriors of the fibers because the cores might be slightly eccentric. It is then preferable to align the exteriors visually as previously described and to align the cores more precisely by passing a light signal from one to the other across their juxtaposed ends and adjusting the alignment to optimize the signal. However, surface tension effects may tend to realign the exteriors as the fibers are fused together. If the cores are indeed eccentric, they will then be misaligned when the fibers are spliced.
The present invention seeks to eliminate, or at least mitigate these disadvantages According to the present invention, apparatus For fusion-splicing two optical fibers comprises:
(i) a pair of supports, for example Vie grooves and associated clamps; one for each fiber, arranged to support said fibers in end-to-end relationship with their ends juxtaposed in a region between the supports;
(ii) electrode means for generating a spark discharge in said region;

39~2~

(iii) mirror means having a mirror surface inclined relative to a common plane for the alignment axis of the fibers and a predetermined viewing direction for reflecting a view of said fibers in a direction transverse to said viewing direction; and iv) means for displacing said mirror means in said viewing direction between a first position close to the fibers, wherein said view from the transverse direction is provided, and a second position further away from the fibers and the viewpoint.
An advantage of this arrangement is that the mirror moves away from the viewer so the fibers can be supported very close to their ends to minimize flexing The electrode means may comprise a pair of electrodes disposed one etch side ox said region so as to define a spark path substantially perpendicular to the alignment axis. The, or at least one of the, electrode means may be movable away from said fibers at least by an amount to provide a view of the corresponding mirror surface unobstructed by such electrode. If a Vie arrangement of two mirror surfaces is provided, both electrodes will be movable.
In preferred embodiments, however, only one mirror surface is provided, and hence only the one corresponding electrode is movable. With such an arrangement the single mirror surface may be positioned so close to the fibers that the difference between the optical paths direct from the fibers, and by way of the mirror, is less than the depth of field of a microscope. Therefore the one view of the fibers will be direct Leo in the viewing direction, and the other via the mirror will be in the transverse direction.

~2~1l3~
Advantageously, the mirror is inclined at 45 degrees to the plane through the alignment axis of the fibers perpendicular to said viewing direction and also intersects such plane. Thus the reflected view is in the direction perpendicular to that of the direct view.
The means for displacing said mirror may serve also to displace the or each electrode. For example, said means for displacing may comprise a plunger having its longitudinal axis, i.e.
axis of reciprocation, substantially aligned with said viewing direction and cam means responsive to reciprocating movement of said plunger for displacing said electrode laterally towards and away from said zone.
In this specification, and the appended claims, the term "alignment axis" is used for the imaginary axis with which the longitudinal axes of the two fibers will coincide when they are properly aligned. The position of this alignment axis will be determined approximately by the support means but will vary slightly due to differences in fiber external diameter and in core eccentricity.
I An embodiment of the invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Figure 1 is a side view of apparatus for fusion-splicing two optical fibers;
Figure 2 is a schematic representation of a part of the apparatus which is for moving one fiber transversely relative to its length;

.

I
Figure 3 is a sectional detailed view on line Z-Z of Figure 1, and Figure PA a corresponding sectional side view;
Figure 4 is a view of the apparatus in the direction of arrow X in Figure l;
Figure 5 is a plan view of -the apparatus;
Figure 6 is an opposite side view of the apparatus;
Figures 7 and are sectional detail views of a gripper jaw of the apparatus taken on line Y-Y of Figure 5;
Figure 9 is a sectional side view taken on line C-C of Figure 4;
Figure 10 is a sectional detail view showing the electrodes in the closed position Figure 11 is a view corresponding to Figure 10 but with the electrodes in the open position;
Figure 12 is a side view of a modified gripper jaw;
Figure 13 is an exploded perspective view of the modified gripper jaw; and Figure 14 is a part-sectional view of a thimble for the modified gripper jaw.
The apparatus illustrated in the drawings is for aligning and fusion-splicing two optical fibers. Features of the apparatus involved in manipulating the fibers are the subject of our cop ending Canadian patent application serial number 440,995, filed herewith, in the name of HUH. Lucas et at and entitled "Apparatus for Aligning an Artiste Relative to a Datum". The apparatus comprises a support member or housing 10 formed from a block of aluminum. The front of the the block 10, i.e.
the face presented to the operator, is stepped from the top and front to form a flat horizontal surface 12 and a generally flat vertical front ,,.

~2~L3~2~

surface 14. A generally rectangular recess 16 is formed in the left side of the block 10, (as viewed from the front) and extends from the bottom of the block 10 to a position adjacent the top of the block.
The recess 16 it central between the front and back of the block 10, occupying about half the depth of the block in that direction. The front wall 18 of recess 16 extends a short distance forward of a continuation of the vertical surface 14.
A second block 19, of aluminum, comprising a first part 20~ a first arm 22, and a second arm 24, occupies the recess 16. The profile of the second block comprising parts 20, 22 and 24, is substantially the same as that of the recess 16, as can be seen from Figure 1. The part 20 is securely anchored in the top of recess 16 by two securing screws 26 and 28. The latter I extends from the left-hand side of the apparatus through anchorage part 20 into the block 10 and the former (26) extends at about 45 downwards through the rear corner of recess 16 into a threaded hole in part 20 so as to draw part 20 tightly into the corner of recess 16.
The anchorage part 20, and arms 22 and 24, are formed from a solid block, being delineated by suitably positioned holes and slots. Thus, a hole 30 extends through the block 19 adjacent its front and top, leaving a narrow neck portion 36. A slot 32, inclined slightly to the horizontal, extends upwards from the rear face of the block 19 to the hole 30. The slot 32 separates the part 20 from the arms 22 and 24 except for narrow neck portion 36 between the hole 30 and the front face 14 of block 19.
From the lower end of neck portion 36, a short recess 38 extends at 45 downwards into the front face 14' of block 19. The I
recess 38 has its upper sidewall 40 undercut at its lowermost part to form a recess 42. A short web of material between the upper sidewall 40 of recess 38 and hole 30 thus forms a flexible hinge member 44 connecting arm 22 to anchorage part 20.
The bottom of recess 38 extends perpendicular to its sidewall 40. A second hole 48 extends through the block 19 at a position slightly below and rearwardly of the bottom surface 46 of recess 38. A narrow portion of material between hole 48 and recess 38, of similar thickness to flexible hinge member 44, serves as a second hinge 50 connecting the proximal part 52 of arm 22 (i.e. that adjacent the hinge 44) to the second arm 24. A vertical slot 54 communicates at its upper end with hole 48 and extends between arms 22 and 24 to the bottom of block 10, permitting relative movement between the arms 22 and 24 in the forward and rearward directions.
As can be seen from Figure 1, the front arm 24 is separated from the front of the recess 16 by a clearance space 60 and the rearward arm 22 separated from the rear face of the recess 16 by a similar clearance 62. These clearances permit slight flexing of the arms 22 and 24 to and fro.
As shown in Figure 2, the rear arm 22 has a screw-threaded hole 64 extending through it from front to rear. The hole 64 is aligned with a recess 66 extending into the rear face of front arm 24. A spring 68 extends from recess 66 into hole 64 and is retained therein by a cap screw 70 screwed into hole 64. The spring 68 acts between the bottom of recess 66 and the screw 70 to urge the two arms 22 and 24 apart. The strength of the spring 58 is much greater than the force required to flex the hinge members 44 and 50.

~2~39~2~

Means for displacing top arms 22 and 24 to and fro comprises eccentrically-mounted cam bearings 72 and 743 respectively.
(See Figure 2.) The cam bearings 72 and 74 cooperate with cam follower pins 76 and 78, which comprise the ends of screws 80 and 82, respectively. Screw 80 extends through the bottom end of rear arm 22 with its end projecting rearward and can be locked by a locking screw 84 extending upwards into the bottom of the arm 22. Screw 82 extends through the bottom of arm 24, with its end projecting forwards, and can be locked in a similar manner by a screw 86 lo extending into the bottom of arm 24.
The cam bearings 72 and 74 are coupled to pinions 88 and I respectively, for rotation thereby. The pinions 88 and 90 engage racks go and 94, respectively, which are connected to corresponding conventional vernier screw mechanisms 96 and 98. The vernier screw mechanisms 96 and 98 are anchored to the block 10 so that adjustment of the vernier spindles 100 and 102 produces reciprocating movement of the respective racks 92 and 94 relative to the block 10.
Both drive mechanisms are similar and one will be described with reference to Figures 3 and PA which show cross-sections through the rear part of the block 10. The drive mechanism is housed in part by a housing 106 comprising a portion 110 of rectangular external shape which has its end reduced in cross-section to form a circular spigot 112 which fits closely into a hole 114 in the side of the block 10~ The spigot 112 is secured by a key 115 in the form of a pin extending tangentially to the spigot 112. The key 115 has a curved indent 116 (see Figure PA) which conforms to the surface of spigot 112. A screw 117, screwed into the I

end of pin 115, urges it outwards, thus clamping the spigot 112 firmly in the hole 114.
The bearing cam 72 is mounted eccentrically on the innermost portion of a shaft 118, which is supported by a pair of bearings 120 and ]21, spaced apart by a spacer sleeve 123 around the shaft 118. The shaft 118 extends into a round concentric cavity 122 in the outer end of rectangular housing portion 110. The gear pinion 88 is securely fixed to the end of shaft 118 in the cavity 122. The housing 106 has a tubular part 124 which extends substantially tangentially to the cavity 122 towards the front of the apparatus.
The vernier drive mechanism 96 is mounted coccal with the tube 124 so -that the rack 92 projects into the tube 124 and engages the pinion MU. The vernier drive sleeve 126 fits into the forward end of tube 124 which is split to form a clamp 108 which is tightened by means of screw 110.
In operation, rotation of the vernier thimble 100 as indicated by arrow A causes movement of rack 92, which rotates pinion 88, and therewith eccentric cam 72. The cam 72 displaces pin 76 to cause arm 22 to move to and fro. This will cause the proximal portion 52 adjacent hinge 44 to pivot about the hinge 44, displacing hinge 50 bodily in the direction of arrow 'A'. The part 130 of second arm 24 proximal the hinge 50 therefore moves in the same direction. This proximal part 130 has a recess 132 of rectangular cross-section extending across it. Recess 132 serves as a mount for a Vie groove 134 which will carry the optical fiber to be aligned.
The sidewalls of recess 132 extend at approximately 45 downwards from the front face of arm 24. The sides of Vie groove 134 are ., 9 I
mutually perpendicular and coplanar with, respectively front face 14' of block 19 and the horizontal surface or apron 12 at the front of the apparatus. When adjustment of vernier thimble 100 produces movement of mount 130 in the direction of arrow 'A', the Vie groove 134 moves likewise, thus displacing the fiber transversely to its length.
It will be appreciated that movement of the proximal part 130 of arm 24 is only slight and is possible despite the fact that forward movement of the lower end of arm 24 is prevented by cam 74. When movement of the vernier 96 produces a corresponding flexing of the hinge 44 to move the mount 132 rearwardly, movement ox the lower part of arm 24 is again prevented, but this time by the spring 68.
Adjustment of vernier 98, as indicated by arrow 'B', will cause its rack 94 to reciprocate thus rotating the pinion 90 and therewith eccentric cam bearing 74, which will cause movement of the cam follower screw 82 in the lower end of arm 24. This will cause the second arm 24 to pivot about its hinge 50. Movement of arm 22 at its lower end is prevented by cam 72 and spring 68, tending to limit movement of its proximal part 52, which is connected to hinge 50.
Thus the mount 132 and the Lee groove 134 will be moved primarily by pivoting about hinge point 50 which, in the case of such smell movements, can be considered as a linear movement in the direction of arrow 'B', i.e. perpendicular to arrow 'A'.
Thus by adjustment of the two verniers 96 and 98, the Vie groove 134 can be moved in two mutually perpendicular directions 'A' and 'B' relative to the longitudinal axis of the fiber in the apex of the groove.

3~2~

Referring now to Figure 4, it will be seen that Vie groove 134 is secured into its underlying recess 132 by two screws 140 and 142, respectively. Its inner end 144 extends in cantilever fashion into a hole 146 which extends through the middle of block 10.
The hole 146 is of rectangular section and extends downwards at 45 to the horizontal, opening onto both horizontal surface 12 and the vertical front face 14. Electrode assemblies 148 and 150, respectively, disposed above and below the longitudinal axis of the Vie groove 134 are mounted in a block 135 of finlike resin, slid ably located in hole 146. The electrode assemblies comprise electrode pins 176 and 178, respectively, which extend end-to-end either side of the longitudinal axis of the fibers when held in the Vie grooves, such that the longitudinal axis of the electrodes intersects that of the fibers.
As shown in Figure 9, the electrodes are connected by two wires 181 and 183, respectively, to an electrical supply (not shown) which, in use, produces a spark discharge across the gap between the ends of the electrodes. The spark discharge thus occurs in the region of the juxtaposed ends of the two fibers and heats them so that they can be fused together.
A second Vie groove 152 is mounted at the opposite (right-hand as shown in Figure 4) side of cavity 146~ The Vie groove 152 is secured by a screw 154 into a corresponding recess and extends with its inner end 156 projecting in cantilever fashion into hole 146 and in substantial alignment with Vie groove 134, i.e., the corresponding surfaces of Vie grooves 134 and 152 are substantially coplanar.

I

Before the fiber is inserted into the apparatus, the outer coating is stripped away from its end for a short distance to leave only the glass cladding and core.
The Use grooves 134 and 152 have grooves 158 and 160, respectively, located in their apexes. The grooves 158 and 160 extend from the outermost ends to a position close to the ends adjacent the center line 162 of the apparatus. The grooves 158 and 160 are of circular cross-sectior, and are arranged to be a close fit for the optical fiber which has not had its outer coating stripped away.
The cylindrical axes of grooves 158 and 160 are aligned with the apexes of their respective Vie grooves 134 and 152. Small rectangular recesses 168 and 170, respectively, extend transversely across the part of the corresponding Vie groove between the end of the groove 158 or 160 and the end of the Vie groove itself. The recesses 168 and 170 each provide a seating for a respective one of the interned ends of a pair of spring fingers 172 and 174, respectively, which serve as grippers for the part of the fiber located in the apex of the Vie groove, which has had its outer coating removed.
The spring fingers 172 and 174 comprise leaf springs mounted upon gripper arms 182 and 184, respectively. Gripper arm 182 is pivotal mounted in a slot 186 which extends into the apron 12 from its upper surface. The arm 182 is mounted upon a pivot pin 188 (see Figures 1, 7 and 8) which extends through the recess 186 with its pivot axis parallel to the fiber axis ~231 39~

Leaf spring 172 is mounted at one end onto the gripper arm 182 by a screw 183. When the arm 182 is in the closed position, the interned end of leaf spring 172 rests in the recess 168, pressing the exposed cladding part of the fiber into the apex of Vie groove 134.
The left-hand Vie groove 134 has a recess 190, its width similar to that of recess 186, to accommodate the gripper arm 182 when the latter is pivoted into contact with the Vie groove. The depth of recess 190 may be such that the gripper arm 182 serves as a clamp to hold the coated fiber part into the circular groove 158 in the Vie groove 134. The arm 182 is spring-loaded by a coil spring 192 (see Figure 7) which acts between the bottom of recess 186 and the interior of a slot 194 in the gripper arm 182 to bias -the latter into contact with the Vie groove 134. A pin 196 extends laterally from arm 182 at a position below pivot pin 188. A push-pull or connecting rod 198 is slid ably mounted in a hole 200 which extends from the recess 186 towards the front of the block lo The push-pull rod 198 is aligned with the pin 196 so that when the push-pull rod 198 is pushed into the recess 186, it contacts pin 196 and rotates the gripper arm 182 out of contact with the Vie groove 134. When the push-pull rod 198 is moved forwards, i.e. out of groove 186, the arm 1~2 returns to the closed position under the action of coil spring 192.
The push-pull rod 198 has a notch 204 at its forward most end. The notch 204 accommodates the end 206 of a lever member 208 which is mounted in a slot 210 in the front of block 10. The slot 210 extends across the entire width of the block 10l Lever 208 is Jo 13 :3L2~3~
secured in the slot by a pivot pin 212 extending vertically through slot 210 at a position adjacent the right-hand side of block 10. The distal part 214 of lever 208 projects outwards from the right-hand side of the block 10 so that it can be pivoted to and fro about pivot pin 212 by an operator. When the lever portion 214 is in the rearward position, shown in full lines in Figure 5, the fiber is clamped. When the lever is moved forwards to the position shown in broken lines in Figure 5, push-pull rod 198 is urged into recess 186 to open the gripper jaw 186. When the arm 182 is fully open the pin 196 overrides the end of push-pull rod 198, as shown in Figure 8, so arm 182 will only return to the closed position again when the push-pull rod is moved forwards, It should be noted that an operator can use his right hand to move lever 208 and open the leFt-hand gripper arm 182 to release the left-hand fiber He can then adjust the position of the left-hand optical fiber using his left hand.
The mechanism for operating gripper arm 184 to open or close the right-hand gripper spring jaw 174 is a mirror image of that for operating the left-hand gripper jaw. Thus, a push-pull rod 216 extends through the front of the block 10 at the right-hand side and engages the end 218 of a second lever 220, the distal end portion 222 of which projects from the left-hand side of block 10. The lever 220 is mounted above the lever 208 in the slot 210 in the front of block 10 and is pivotal about pivot pin 224 adjacent the left-hand side of the block 10. Thus, the operator will use his left hand to operate lever 220 to release the right-hand gripper mechanism, while using his right hand to adjust the position of, or insert, the right-hand optical fiber in the groove 156.

~2~3~

Unlike the left-hand arm 182, gripper arm 184 it not mounted directly into lock 10. Rather, arm 184 is mounted in a recess 230 in the end of a lever 232. The lever 232 extends towards the rear of the block 10 in a recess 234 in the right-hand side of the block 10. The arm 184 is mounted upon a pivot pin 236 extending laterally through the Levis formed by the recess 230 in the forward end of lever 232, and has a pin (not shown) to be engaged by the end of push rod 216 in like manner to that of the left-hand gripper jaw mechanism.
The upper front portion of lever 232 is stepped to provide a vertical surface 240 and a horizontal surface 242 substantially coplanar with the corresponding surfaces of the groove 156. The surfaces 240 and 242 have a central recess 244 to accommodate arm 184 when it is in the clamping position such that the pivot arm 184 will clamp the outer coating of the optical fiber into the apex of the Vie groove formed by surfaces 240 and 242.
The lever 232 is pivotal mounted in the recess 234 by a pivot pin 246 extending through suitably aligned holes in the block 10 and lever 232, respectively, from the underside of the block 10.
A recess 235 (see Figure 5) in the inner face of lever 232 houses a return spring 248 which blesses the front portion of lever 232 outwards, i.e., towards the right as shown in Figures 4 and 5.
When the outer coating of the fiber is gripped by pivot arm 184, pivotal movement of lever 232 about pivot pin 246 will cause the fiber to be moved in the direction of its length. The fiber will thus slide along the Vie groove 156, such movement being permitted by the leaf spring 174. Longitudinal movement of the fiber is required Z~3gL~

during the sequence of operations, in which the fibers are separated slightly while being heated, then pushed together to cause their ends to fuse.
Lever 232 is actuated by means of a mechanism at the rear of block 10~ as illustrated in the cut-away view of Figure 5 and in Figure 9. The mechanism comprises a cam 250 mounted upon a shaft 252 extending vertically in a cavity 254 at the rear of block 10.
The shaft 252 is mounted in bearings 249 and 251, respectively, and is rotatable by a motor 253 located below a face plate 255 beneath the block 10. The cam 250 is positioned adjacent a hole 256 which extends between recess 254 and the recess 234 in the side of block 10. A ball 258 is located in hole 256 and serves as a cam follower.
The ball is in contact with the end of a screw 260 which extends through a suitably screw-threaded hole 261 in the rear end of lever 232. A second screw, 262, extends through lever 232 from the outside and is arranged to abut the bottom of recess 234. Screw 262 serves to limit the movement of the rear part of arm 232 into the recess 234 when the cam 250 is rotated so that it is no longer in contact with ball 258.
Screws 260 and 262 control the separation of the fibers before and during the heating process by the spark discharge. Thus, in the position shown in Figure 5, the lever 232 is in its initial position ready for insertion of the two optical fibers. The operator inserts the two optical fibers end-to-end after releasing the gripping springs 172 and 174 as described previously. Initially, the fibers are butted end-to-end such that the end surfaces meet in the plane of the two electrodes 176 and 178. The fibers are then held Lo firmly by the gripping springs 172 and 174. The motor 253 is actuated for a short time. The separation cam 250 rotates, its lobe disengages ball 258 and allows the lever 232 to pivot inwards at the rear until screw 262 bears against the bottom of the recess 254.
This gives the required separation of the ends of the fibers. The slight separation is required to permit relative movement of the ends of the fibers transversely to their longitudinal axes. The fibers are then manipulated using the vernier mechanisms which move the Vie groove 134 transversely relatively to the other Vie grow 156.
During initial alignment in this way, the relative positions of the two fibers in the two directions 'A' and 'B' are observed with the aid of a mirror 270 disposed beneath the spark Noah. The inclined surface ox the mirror 270 extends towards the observer beyond the axis of the electrodes, so that, when viewed in the direction of arrow X of Figure 19 the mirror provides a lateral view of the two fibers. The lower electrode 178 is movable away from the other electrode to allow the mirror to be interposed. The mechanism for moving the mirror will be described in more detail hereafter.
After initial alignment of the exteriors of the fibers using such visual inspection, precise alignment of the cores is done while monitoring the passage of a light signal across the gap between the fibers. Circuitry for supplying and detecting the light signal may be of conventional construction and so is not depicted.
Manipulation of the Fibers during the precise alignment stage using the light signal is still carried out using the vernier mechanisms 96 and 98.

~2~3~

A second cam 264 is mounted on shaft 252 at a position slightly below cam 250. The lobe of cam 264 is diametrically opposite that of cam 250. A second ball 265, in a corresponding hole 267, serves as a cam follower and acts between cam 264 and the end of a third screw 266 which extends through the lever 232 at a position slightly below screw 260. (See Figure 6.) Screw 266 has at its outer end a head or knob 268 and carries a coil spring 271 which acts between the surface of lever 232 and the underside of head 268 to eliminate play and provide friction to ensure that undesired movement of the screw 266 is prevented.
Once the fibers have been precisely aligned, the motor is actuated to rotate shaft 252. Rotation of shaft 252 lowers the mirror 270, restores electrode 178 to its operative position, and closes a switch to initiate the spark discharge. During the spark discharge, shaft 252 continues to rotate and, when the spark discharge has heated the fibers sufficiently, cam 264 actuates the associated ball 265 and displaces the rear part of the lever 232 outwards causing it to push the right-hand fiber back towards the center line of the apparatus. In order that the fibers will fuse, it is necessary for the right-hand fiber to be pushed beyond its original position. The lift of cam 264 and position of screw 266 are arranged to provide such additional movement. The extent of the additional movement of the end of the right-hand fiber beyond the axes of the electrodes may be adjusted by knob 268.
The electrode assemblies 148 and 150, their associated operating mechanism, and the mirror 270 are shown in more detail in Figures 9, 10 and 11. As previously mentioned, the electrode I
assemblies 148 and 150 are mounted upon an insulator block 135 of finlike resin material (or any other suitable insulating material) in hole 146 in the middle of the block 10. A lamp 28Q is located in a hole 282 extending from the upper, rear corner of block 10 to hole 146 at a position adjacent the electrode pins 17~ and 178 and serves to illuminate them and the ends of the fibers.
The insulator block 135 is of 'I' cross-section and the electrode assemblies 148 and 150 are accommodated one in each of the two channels of the I section. The fixed electrode assembly 148 I (shown uppermost in Figures 1 and 4 and at the left in Figures 10 and 11) comprises an elongate brass bar 284 located at one end relative Jo the insulator block 135 by a pin 286 extending through the flanges of the block 135 adjacent its lowermost end. The end of the bar 284 has a notch 287 which engages the pin 286 to locate the bar 284 longitudinally. The bar 284 is biassed towards the central web portion 288 by a leaf spring 294 which is attached to the bar 284 at one end and bears against a terminal post 296. The bar 284 lies flat against the central web portion 288 of the insulator block 135 and protrudes slightly beyond the uppermost end of the web portion 288.
Electrode pin 176, of sistered tungsten or other suitable material, extends transversely through the protruding end of bar 284 and is secured thereto by a screw 290 extending into the end of the bar 284.
The tip of electrode 176 is arranged to be aligned with the longitudinal axis of the fibers when they are correctly positioned.
An adjustment screw 291 extends into the bar 284 from one side to impinge upon the electrode pin 176. This screw 291 permits small lateral adjustments of tune electrode 176.

I

A cylindrical handle 292, of insulating material, is secured to the protruding end of bar 284 so as to extend beyond the end of the insulator black 135. The electrode assembly 148 can be removed by pulling the handle 292, the notch 287 disengaging the pin 286 with a "snap-action". Electrical connection to the electrode pin 176 is by way of the leaf spring 294 and terminal pin 296, which is connected to the high voltage spark generator (not shown) by wire 181.
The movable electrode assembly 150 is similar in construction to the fixed electrode assembly 148~ When in the "spark-discharge" position, shown in figure lo it is a mirror-image of electrode assembly 1~8, and comprises a corresponding set ox components, namely an elongate brass bar 300, located relative to the block 135 by d pivot pin 302 and having its own electrode pin 178 secured by a screw 304 to an end portion which carries an insulating handle 306. Lateral adjustment of the electrode 178 relative to bar 300 is by means of adjustment screw 305. The electrical connection is by way of a corresponding leaf spring 308 bearing against a terminal pin 310, which is connected to the spark generator by wire 183.
The main difference is that the movable electrode assembly 150 is pivotal about its locating pin 302 so as to displace its electrode 178 outwards from the axis of the fibers. Such displacement is achieved by means of a rod or plunger 314 which is slid ably housed in a hole 316 extending through the central web portion Z88 of the insulator block 135. The cylindrical axis of the plunger 314, the fiber axes, and the spark discharge path between the electrodes 176 and 178 are substantially mutually perpendicular.

LIZ
The plunger 314 is prevented from rotating by a pair of set screws 318 which extend through opposite sidewalls of the web portion 288. Each set screw engages a corresponding one of two flats 320 on opposite sides of the plunger 314. Only one set screw and one flat are shown.
The lower end of the plunger 314 extends beyond the insulator block 135 and has a surrounding flange 322. A compression spring 324 carried by the plunger 314 acts between the end of insulator block 135 and the flange 322 to urge the plunger 314 downwards i.e. away from the electrodes 176 and 178, to the position shown in Figure 10. In this position, a cylindrical indent 326 in the plunger 314 is aligned with an elongated hole 328 which extends through the insulator block, including the web portion 288, adjacent the electrode arm 300. A roller 330, of insulating material, located in the hole 328 seats in the indent 326 and permits the arm 300 to lie flat against the juxtaposed surface of web portion 288.
Consequently, the electrode 178 is in proximity to the fibers so that spark discharge may take place.
It should be noted that, during the spark discharge, the I end of plunger 314, which carries the mirror 270 (extending at 45 to its longitudinal axis) is spaced well below the electrodes 176 and 178 to ensure that the mirror 270 is not spattered during the spark discharge step.
When the plunger 314 is displaced towards the electrodes 176 and 178, against the action of spring 324, the roller 330 is displaced out of indent or seating 326 and forces the electrode arm 300 away from the central web portion 288. This displaces electrode :12~3~Z~
178 outwards to the position shown in Figure 11. At the same time, the mirror 270 is repositioned in close proximity to the fibers, As can be seen in Figure 11, the mirror 270 actually extends beyond the plane occupied by the fiber axis and the spark discharge path. With the mirror 270 in this position, the fibers can be viewed directly in the direction of the longitudinal axis of the plunger 314. At the same time, the image of the fibers in mirror 270 can be viewed, giving the view of the fibers in a perpendicular direction i.e., in the direction of the spark discharge path. The fibers can thus be aligned visually. The plunger 314, and with it mirror 270, can then be withdrawn, electrode 178 restored to its operative position, and -the spark initiated Displacement of the plunger 314 is by means of a third cam, 334, on shaft 252. As shown in Figure 9, cam 334 acts against the lower end of plunger 314. The shaft 252 also carries two cams, 336 and 338, respectively, beneath the faceplate 255. Cams 336 and 338 cooperate with corresponding limit switches 340 and 342 to control the spark discharge and the motor cycle, respectively.
A significant advantage of the displaceable mirror described herein before is that the mirror can be positioned very close to the fibers during the alignment procedure. Consequently, the optical path via the mirror 27~ is only slightly longer than that direct from the fibers. Therefore both the fibers and their image can be viewed without refocusing the microscope through which they usually are viewed. This simplifies the operating procedure since it is usual to focus directly upon the fibers to inspect their ends for satisfactory cleaving and freedom from contamination, then carry out , I; ,. . . .

~2~L3~24 the alignment. Another advantage of this configuration is that a single planar mirror can be used which is much easier and cheaper to make than the Vee-shaped mirrors used hitherto. Also, a single mirror surface does not present problems of alignment with the fiber axis and optical axis of the microscope, which might occur with Vee-shaped mirrors in view of the precision required.
Various modifications are possible without departing beyond the scope of the present invention. One particular modification involves the gripper jaws and is illustrated in Figures 12 and 13. In the previously described embodiment the gripper jaws comprise spring fingers 172 and 174, the interned ends of which bear as knife edges against the fibers to clamp them into the apexes of the Vie grooves.
In Figure 12~ a part of gripper arm 182 is shown. A
channel-shaped member 350 is secured to the end of the gripper arm 182 so as to extend parallel to the Vee-groove 134 and with its channel facing away therefrom. A tappet member in the form of a thimble-shaped member 352 is slid ably located in a hole 354 extending through the base of the channel member 350 adjacent its distal end.
A wire spring 356 is secured at one end to the gripper arm 182 by a screw 357, extends along the channel, and has its other end angled into the thimble-member 352.
A cover plate 358, also secured at one end to the gripper arm 182 extends along the mouth of the channel to cover the wire spring 356. The spring 356 urges the thimble member 352 lightly into contact with the fiber when the gripper arm is closed. It should be noted that the end surface of the thimble-member 352 is ~2~3~

substantially flat so as to contact the fiber over a relatively large distance. Moreover, the corresponding internal end surface of the thimble-member 352 is formed as a conical seating 360. The end of the spring 356 cooperates with the seating 360 to permit slight pivoting of the thimble-member 352 to facilitate proper, flat seating of the thimble-member 352 against the fiber.
Although the preferred embodiment has a single mirror, inclined at 45, the invention still comprehends apparatus in which a Vie mirror, or a pair of mutually-inclined separate mirror surfaces are used to provide the two views of the fibers. Then both electrodes will usually be movable to allow the mirror to be positioned close to the fibers and/or to ensure they do not obstruct the view of -the mirror surfaces.
Although particularly useful for single mode fiber, the apparatus can be used to advantage with multimedia fiber. Moreover, especially when aligning multimedia fiber, the light signal might be dispensed with and the fiber position monitored solely visually ,, . . ,

Claims (9)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. Apparatus for fusion-splicing two optical fibers, comprising:-(i) a pair of supports each arranged to support one of said fibers in end-to-end relationship to the other fiber such that the juxtaposed ends of said fibers are juxtaposed in a predetermined region between said supports;
(ii) mirror means having a mirror surface inclined relative to a common plane of the alignment axis for the fibers and a predetermined viewing direction for providing an image corresponding to a view of said fibers taken in a direction transverse to said viewing direction, said mirror means being displaceable in said viewing direction between a first position close to said alignment axis, wherein said mirror means can provide said image, and a second position further away from said alignment axis and the viewpoint;
(iii) electrode means for generating in said region a spark discharge for heating the end portions of fibers inserted therein, said electrode means comprising a pair of electrodes disposed one on each side of said region and of said alignment axis, one of said electrodes being movable between a first position adjacent said alignment axis for generation of said spark discharge and a second position further away from said alignment axis wherein the electrode does not obstruct the view of the mirror from said viewing direction; and (iv) common actuating means for displacing said mirror means and said one of said electrodes, said common actuating means comprising a support for said mirror and cam means acting between said support and said one electrode, such that movement of the mirror means into its said first position causes said one electrode to assume its said second position, and movement of said mirror means into its said second position causes said one electrode to assume its said first position.

2. Apparatus as claimed in claim 1, wherein said electrode means comprises a support block having two channels, one in each opposite side, the channels extending lengthwise in a direction away from said alignment axis, a pair of arms each carrying one of said electrodes, said arms being slidably located one in each of said channels, and spring means urging each of said arms into the corresponding channel thereby engaging detent means for locating said arm against longitudinal movement relative to said channel.

3. Apparatus as claimed in claim 1, wherein said one electrode is mounted on a pivotal arm for pivotal movement between said first and second positions.

4. Apparatus as claimed in claim 2, wherein the one of said arms carrying the movable electrode is pivotal for movement of said electrode between said first and second positions.

5. Apparatus as claimed in claim 1, wherein said electrodes are releasably mounted on said electrode means.

6. Apparatus as claimed in claim 2, wherein said electrodes are releasable mounted on said electrode means.

7. Apparatus as claimed in claim 1, wherein said common actuating means comprises a plunger with its axis of movement substantially aligned with the viewing direction, said cam means being responsive to reciprocating movement of said plunger to displace one of said electrodes between its first and second positions.

8. Apparatus as claimed in claim 7, wherein said support block comprises a through hole extending in the viewing direction and said plunger is slid ably located in said hole, said cam means acting between said through hole and one of said channels to transmit movement of said plunger to the arm supporting the movable electrode.

9. Apparatus as claimed in claim 7 or 8, wherein said mirror means comprises a single surface on one end of said plunger and inclined at substantially forty-five degrees to the plane extending through said alignment axis perpendicularly to the viewing direction, movement of said plunger being such that said single surface intersects said plane when said mirror means is in said first position.