AU3159395A

AU3159395A - Fusion splice element

Info

Publication number: AU3159395A
Application number: AU31593/95A
Authority: AU
Inventors: Gordon A Clark; Murray R Harman; James D. Marshall
Original assignee: Preformed Line Products Canada Ltd
Current assignee: Preformed Line Products Canada Ltd
Priority date: 1994-08-11
Filing date: 1995-08-11
Publication date: 1996-03-07
Also published as: WO1996005527A1; CA2197184A1; EP0774127A1; MX9701027A; BR9508576A

Description

FUSION SPLICE ELEMENT

Field of the Invention

This invention relates generally to a fusion element and more particularly to an element for use in splicing optical fibers.

Cross-References to Related Applications

This application is related to, and a continuation- in-part application of, co-pending application Ser. No. filed August 11, 1994 entitled: FUSION

SPLICING BLOCK which was a continuation-in-part application of co-pending application Serial No. 08/266,205, filed June 27, 1994 and is also related to, and a continuation-in-part application of, co-pending application Ser. No. filed August 11, 1994 entitled TOOL FOR FUSING OPTICAL FIBERS which was a continuation-in-part application of co-pending application Serial No. 08/266,205, filed June 27, 1994.

Background of the Invention

Fusion splicing devices have been well known for some time and many of these devices are commercially available. One such device is described by the applicant in U.S. patent 5,002,351 issued March 26, 1991 entitled Splicer for Optical Fibers. Another such device is described in U.S. patent 5,146,527 in the name of Mallinson issued September 8, 1992. Mallinson's fusion splicer is designed to receive a consumable ferrule, having a bore through a central longitudinal axis, for accommodating two fiber ends for fusion within. A slot is formed in the ferrule into which permanent electrodes are temporarily inserted for fusing optical fibers positioned within the bore. U.S. patent 4,598,974 issued July 8, 1986 in the name of Munn et al described an optical fiber connector having integral electrodes. Although Munn's device relates specifically to a connector having a pre-inserted optical fiber stub, it is possible to adapt this design to a fusion sleeve for fusing two unclad optical fiber ends.

Another more recently issued U.S. patent, number 5,222,171 issued June 22, 1993 in the name of Straus, describes a sleeve similar to Munn's having integral electrodes and axial alignment means.

Although the devices described in the aforementioned patent appear to adequately perform their intended functions, it is an object of this invention to provide a fusion splice element that forms an enclosure over fused optical fibers housed within. Such a fusion element would provide a relatively clean fusion cavity in which fusion may take place. In addition, the fibers need not be inserted into a guide hole where debris could come into contact with the end of the fiber, thus causing degradation of the fusion joint. The fibers instead can be placed into an alignment groove and remain clean. After fusion, the splice element is closed upon the fused optical fibers and remains with the spliced fused fibers providing a rigid support and strain relief for the fusion joint within. The fused fibers within the splice element remain in a clean protective environment. Alternatively, as will be described in greater detail, fusion may take place within a closed fusion element after a base portion and lid are sealed close.

In accordance with the invention, an optical fiber splice element is provided comprising a base member having a fusion element for housing optical fibers for fusion within; and, a covering member for covering and forming an enclosure with the base member in a closed portion, at least one of the covering member and the base member having means for preserving closure in a closed position, the optical fiber enclosure in an open position having a channel at either end for accommodating one or more optical fibers.

SUBSTITUTE SHEET (RULE 26 Brief Description of the Drawings

Exemplary embodiments of the invention will now be described in conjunction with the drawings in which:

Fig. l is an oblique view of a splice sleeve having a built-in ceramic fusion block;

Fig. 2 is a top view of the splice sleeve in Fig. 1 including an optical fiber inserted in one end;

Fig. 3 is an oblique view of the base portion of an alternative embodiment of a splice sleeve; Fig. 4 is an oblique view of a splice sleeve having a separate base and lid; and

Figs. 5a and 5b are oblique views of splice sleeves each having hinged lids with multiple sections.

Detailed Description

Referring now, to Fig. l and Fig. 2, an optical fiber splicing element is shown in the form of a "butterfly" splice sleeve 10. A base portion 12 of the sleeve 10 is hingedly connected to a covering member in the form of a lid 14. A fusion member shown as a ceramic block 20 is located centrally within the base portion 12 of the sleeve 10. Two conductive copper tracks 24 are each electrically connected by a copper plated barrel of a through hole 26 to a conducting pad (not shown) on the underside of the ceramic block 20. The copper tracks 24 can be bonded to the ceramic block 20 by being printed, glued, or plated thereon. The end 25 of each copper track 24 forms an electrode. A V-groove is provided in the splicing element for guiding the optical fiber in an alignment groove 28 in the ceramic block 20. When the lid 14 is closed on the base portion 12, holding means shown as protrusions 16 in the lid abut and hold optical fibers securely within the groove 22. The protrusions 16 are somewhat compliant and preferably resilient so that they form around the fibers and tightly squeeze the fibers without damaging them, yet at the same time, provide clamping upon the fibers serving as a strain relief for a fusion joint within the sleeve 10. An outer lip 30 on the lid 14 provides a means of securing the lid in a closed position as it engages the underside of the lip 32 on the base portion 12 of the sleeve 10. In operation, two optical fibers (not shown) are placed into the base portion so that their ends hang over the opening 33 in the ceramic block 20. In Fig. 2 one optical fiber 37 is shown inserted. After the fibers are in place and are ready to be fused, a sufficiently large voltage is applied across the conducting pads (not shown) to generate an electric arc across the tips of electrodes 25 so, as to melt and fuse the ends of the fibers together. The lid 14 is then closed to secure and retain the fused fibers within the splicing element 10. Alternatively, the fibers could be placed into the base portion 12, ready for fusion with the lid 14 being closed to retain the fibers. An electric arc could then be generated across the electrode tips to cause the fiber ends to fuse together. In such an embodiment, it may be preferable to provide a transparent window over the cavity defined by the region above the ceramic block. In either case, a piece of removable tape can be provided that normally covers the groove 22 and the ceramic block 20 before optical fibers are placed within. The removable tape is provided to ensure cleanliness of the groove and the ceramic block during storage and handling. Turning now to Fig. 3, an alternative embodiment of a fusion sleeve is shown. A base member 40 includes an optical fiber channel guide on each side of a passline 44 indicated by a dotted line. The passline 44 defines an access path for external electrodes for fusing optical fibers supported by the base member 40. A ceramic alignment block 46 is provided for supporting unclad portions of the optical fiber ends that are to be fused. In Fig. 4 a splice sleeve is shown having a base member 50 and seperate lid 54. The base member 50 contains a ceramic block 54 for supporting optical fibers that are to be fused. After fusion takes place the lid 54 is secured to the base member 50 covering and protecting fused fibers within.

Figs. 5a and 5b show alternative hinged lid arrangements. In Fig. 5a, a sealed port 60 is shown in the central fusion portion of the sleeve for viewing of the fusion cavity within. In Fig. 5b a sleeve is shown having a base 70 that includes two lids 72 hinged at the ends of the base 70. Of course, numerous other embodiments may be envisaged, without departing from the spirit and scope of the invention.

SUBSTITUTE SHEET (RULE 26

Claims

What I claim is:

1. A optical fiber splice element comprising: a base member having a fusion element for aligning optical fibers for fusion within; and a covering member for covering and forming an enclosure with the base member in a closed position, at least one of the covering member and the base member having means for maintaining closure in a closed position, the optical fiber splice element in an open position having a channel at either end for accommodating one or more optical fibers.

2. An optical fiber splice element as defined in claim 1, wherein the fusion element includes electrodes.

3. An optical fiber splice element as defined in claim 1, wherein the base member and the covering member are hingedly attached.

4. An optical fiber splice element as defined in claim 1, wherein the means for maintaining closure in the closed position is at least one of adhesive means, and latching means.

5. An optical fiber splice element as defined in claim 1, including holding means for securing optical fibers contained within.

6. An optical fiber splice element as defined in claim 5, wherein the base member includes a groove for accommodating and supporting the optical fibers, and wherein the holding means are in the form of protrusions extending from the covering member and at least partially extending into the groove defined in the base member when the enclosure is in the closed position.

SUBSTITUTESHEET(RULE23

7. An optical fiber splice element as defined in claim 6, wherein the protrusions are at least partially resilient.

8. An optical fiber splice element as defined in claim 5, wherein the covering member includes a viewing port of viewing optical fiber ends, contained within.

9. An optical fiber splice element as defined in claim 1, wherein the fusion element is made of a ceramic material.

10. An optical fiber splice element as defined in claim

I, wherein the fusion element is comprised of a non- conducting substrate and includes: a pair of electrodes, each electrode having an electrode tip end and having another end for contacting a voltage source, a portion of each electrode overlying a surface of the non-conducting substrate, and spaced apart and separated from each other by the passline such that each electrode tip end is adjacent to the passline, the electrode tips defining an arc region therebetween.

11. An optical fiber splice element as defined in claim 10, wherein the surface of the non-conducting substrate is substantially planar.

12. An optical fiber splice element as defined in claim

II, wherein a portion of the electrode overlying the surface of the non-conducting substrate is bonded to the substrate.

13. An optical fiber splice element as defined in claim 12, wherein the electrodes are printed, glued, or plated thereon.

14. An optical fiber splice element as defined in claim 12, further comprising a layer of non-conducting material substantially covering the electrodes bonded to the non¬ conducting substrate.

15. An optical fiber splice element comprising: a base member having a fusion element for housing optical fibers for fusion within; and a hinged covering member for covering and forming an enclosure with the base member in a closed position, at least of the covering member and the base member having means for maintaining closure in a closed position, the optical fiber splice element in an open position having an opening at either end for accommodating one or more optical fibers, the fusion element being comprised of a non-conducting substrate, the electrodes having ends defining tips that are separated to define a fusion cavity.