CA1052604A

CA1052604A - Fiber optic connector with transparent cable sleeve

Info

Publication number: CA1052604A
Application number: CA251,170A
Authority: CA
Inventors: Eleanor A. Landgreen
Original assignee: ITT Industries Inc
Current assignee: ITT Inc
Priority date: 1975-04-28
Filing date: 1976-04-27
Publication date: 1979-04-17
Also published as: US3984174A; IT1060049B; NL7604196A; JPS52432A; DE2611686A1

Abstract

FIBER OPTIC CONNECTOR WITH TRANSPARENT CABLE SLEEVE

ABSTRACT OF THE DISCLOSURE

A fiber optic cable for use in a fiber optic connec-tor having a transparent sleeve formed on the end of the fiber optic bundle of the cable. The end of the sleeve is closed and extends over the end surface of the bundle to form an optical window therefor and a protective spacer so that when two cables are mated in abutting relationship the end surfaces of the fiber bundles are spaced apart, preventing end surface bundle scratching which causes excessive light diffusion and results in light reception losses.

Description

~5'~6~4 E. A. Landgreen 2 BACKGROUND ()F TEIE INVENTION
The present invention relates to connectors and, more specifically, to connectors for fiber optic cables.
The employment of fiber optic cables or light guides, also sometimes referred to as optical communication fibers, for the transmission of information-bearing light signals, is now an established art. Much development work has been devoted to the provision of practical low-lose glass materials and production techniques for producing glass fiber cables with protective outer coatings or jackets. The jacket makes them resemble ordinary metallic-core electrical cable upon superficial external inspec-tion. Obviously, if fiber optic cables are to be used in practical signal transmission and processing systems, practical connectors fox the connection and disconnection of fiber optic cables must be provided.
Before the prior art in respect to connectors, per se, is discussed, some references will be given for background in the state of fiber optic art in general.
An article entitled, "Fiber Optics", by Narinder S.
20 Kapany, published in Scientific American, Vol. 203, pgs. 72-81, ~ovember 1960, provides a useful background in respect to some theoretical and practical aspects of fiber optic transmission.

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-2-~5~04 E. A. Landg~een 2 Of considerable relevance to the problem of develop-ing practical fibex optic connectors, is the ~uestion of transEer efficiency at the connector. Various factors, including separation at the point of abutment, and lateral separation or offset, are among the factors effecting the light transfer efficiency at a connector. In this connection, attention is directed to the Bell S~stem Technical Journal, Vol. 50, No. 10, December, 1971, specifically to an article by D. L. Bisbee, entitled, "Measurement of Loss Due to Offset, lQ and End Separations of Optical Fibers". Another Bell Sy-stem Technical Journa~ article of interest appeared in Vol. 52, No. 8, October, 1973, and was entitled, "Effect of Misalign-ments on Coupling Efficiency on Single-Mode Optical Fiber Butt Joints", by ~. S. Cook, W. L. Mammel and R. J. Grow.
The patent literature also contains much information relative to the s~ate of this art. For example, U. S. Patent No. 3,624,816 describes a "Flexible Fiber Optic Conduit".
The device described therein uses a plurality of light conduc-ting fibers in a flexible cable-type arrangement.
Concerning the utility of fiber optic cables and, therefore, the utility of connectors for such cables, various systems are described in the patent literature which employs fiber optic cables. One example of such a utilization system is described in U. S. Patent No. 3,809,908, "Electro-Optical Transmission ~ine".
~ et another patent of interest is entitled, "Glass Fiber ~ptical Devices", U. S. Patent No. 3,589,793. This reference relates to the fiber optic bundles and the glass fibers themselves as well as to a method of fabrication for the fiber optic elements themselves.

E. ~. Land~xeen 2 1()5'~tj04 A selection of U. S. patents relating more particulax-ly to optical cable connectors includes U. ~. Patents Nos.

3,790,791; 3,734,594; 3,637,284; 3,572,891; 3,8Q6,225; 3,7~8, 189 and 3,508,807. These patents are representative of the connector prior art.
A fiber bundle-to-fiber bundle connector design re-quires the polished bundle ends to be positioned and held in close proximity. The most direct way to accomplish this is to butt the bundle ends together. When the`ends of the fiber bundles are in abutting contact, repeated matings o~ the con-nector members in which the bundles are mounted and movement due to vibration can cause bundle surface scratching, especi-ally when grit is present in the connector. The result is excessive light diffusion, causing optical losses at the abut-ting bundle interface. Losses due to surface scratching mayamount ko 4 dB or more. Thé purpose of the present invention is to provide a fiber optic cable arrangement which eliminates scratching of the end surfaces of the fiber bundles with opti-cal power losses less than that which results from surface scratching.
SUMMARY OF THE INVE~TIO~
According to the principal aspect of the present in-vention, there is provided a fiber optic cable for use in a fiber optic connector wherein a transparent sleeve surrounds -25 the end of the fiber op~ic bundle of the cable. The sleeve has a closed end extending over the planar end surface of the fiber bundle forming an optical window for the bundle. The sleeve has an index of refraction substantially matching that of the fibers in the bundle. When two fiber optic cables hav-ing such sleeves thereon are brought into axial abutting con-tact with each other in a fiber optic connector, the sleeves .~, .. . .

'. , . .

1~5~04 E~ A. Landgreen 2 provide protec-tive spacers, spacin~ the end surfaces of the bundles apart, thereby preventiny scratching of the bundle ~ -end surfaces. Thus, the present invention eliminates optical losses due to excessive light diffusion resulting from the scratching of the end surfaces of the fiber bundles. The closed ends of the sleeves are sufficiently thin so that the gap between the fiber bundle ends results in only minor losses in optical transfer between the cables. The transparent sleeve also avoids the need for a highly polished optical fiber end surface.
BRIEF DESCRIPTION OF THE DR~WINGS
Fig. 1 is a partial cutaway perspective view of a fiber optic connector showing the connector members mated and a single pair of signal connected fiber optic cables therein;
Fig. 2 is a fragmentary partial longitudinal sectional view of the connector showing the details of structure of the abutting ends of the fiber optic cables employed in the connec-tor having protective sleeves thereon;
Fig. 3 is an end view of one of the cables illus~rated in Figs. 1 and 2 with a portion of the protective sleeve re-moved; and Fis. 4 is a longitudinal sectional view through the end portion of a modified form of the cable of the present invention.
DESCRIPTION OF THE PREFERRED EMBODI~ENTS
Referring now to Figs. 1 to 3 of the drawings in de-tail, there is illustrated a fiber optic connector assembly generally designated 10 comprising a plug connector member 12 mated to a receptacle connector member 14. The plug connector memher 12 comprises a shell 13 containing a support member 16 which supports a plurality of fiber optic cables 18, only one .

- E. A. L~nd~reen 2 105;~6~4 being illustrated for purposes of clarity. It is noted that the support member 16 contains four axially extending passages 20 therethrough for holding fiber optic cables. It will be appr,eciated that any number of cables may be mounted in the connector member 12.
The mating receptacle connector member 14 also includes a shell 22 containing a support member 24 for fiber optic cables 26 equal in number to the cables 18 in plug connector member 12 and axially aligned therewith. The shell 22 has a mounting flange 27 thereon for mounting the connector 10 to a suitable panel or the like. The plu~ connector member 12 carries a rotatable coupling nut 28 havin~ an arcuate slot 30 therein which cooperates with a pin 32 on the shell 22 to provide a bayonet connection between the two connector members, as well known in the electrical connector field, which allows the two connec~or members to be mated upon rotation of the coupling nut 28.
The support members 16 and 24 in the connector shells may be single pieces or multiple piece arrangements, as illus-trated in Fig. 1.
The ~iber optic cables 18 and 26 are identical and, therefore, only one of such cables 18 will be described, it being understood that the description thereof is applicable to the other cable 26. The various components of the cables will be designated by the same reference numerals. The cable 18 comprises a fiber optic bundle 34 with a jacket 36 surrounding the bundle. ~ termination pin 38 terminates the end of the bundle 34. Preferably, the pin is a hollow body having at least one axially e~tending slot 40 therein which extends from the forward end 42 of the body a predetermined distance toward the rear end thereof. Preferably, a pair of slots are provided, E. ~, L~nd~reen 2 1~5'~04 as best seen in Fig. 3. This arrangement provides a "split tine" or "spring tine" device for firmly ~ripping and com-pressing the indivi~ual glass fibers in the fiber bundle 34 in the vicinity of the point of interface abutment between the cables 18 and 26. An epoxy cement adhexes the fibers together within the pin and Eills any voids between the fibers at the end of the bundle 34.
A collar 44 is slidable on the pin 38 behind an annu-lar groove 46 in the pin. A spring retention element 48 is mounted in the support member 16 surrounding the collar ~4 The retention element has a pair of forwardly and inwardly extending spring fingers 50 engaging a rearwardly facing shoulder 52 on the collar 44 limiting rearward movement of the termination pin 38 in the support member 16. The pin is also formed with a forwardly facing tapered shoulder 54 which engages a rearwardly facing surface 56 on the support member 16 to limit forward movement of the termination pin in the connector. A resilient annular ring 58 lies within the groove 46. The mounting arrangement for the termination pin on the cable 26 may be identical to that employed in the support member 16 for the termination pin on cable 18.
When the connector members 12 and 14 are mated to-gether, the ends of the termination pins 38 for the two fiber optic cables 16 and 26 are adjacent to each other. In order to assure that axial alignment is achieved between the opposed te~mination pins, an elastomeric sleeve 60 is provided in a recess 62 in the support member 16. The sleeve surrounds the abutting ends of the pins 38. The length of the sleeve 60 is greater than the distance between the front face 64 of the support 16 and the bottom 66 of recess 62 so that when the connector members are mated the support member 16 will apply - E. A. Land~reen 2 ~05;~0~
compressive force to the end of the sleeve 60 causing it to contract radially inwardly, tightly fitting around the ends of the pins 38 and effecting a very accurate axial alignment therebetween.
The specific structure described herein for the termination pin 38, the mounting arrangement therefor in the support 16, and the axial alignment sleeve 60 are given by way of example only and constitute no part of the present invention. As will be seen from the following description, the advantages of the present invention will be achieved in any fiber optic connector wherein fiber bundles are axially aligned in abutting relationship. In accordance with the invention, a transparent protective sleeve 70 is provided over the forward ends of the aligned fiber bundles so that the faces of the bundles will be spaced apart and will not be subject to abrasion as normally occurs when the bundles are mated in direct abutting relationship. Preferably, the forward end of the fiber bundle 34 and the end surface 42 of the pin 38 are polished to provide a coplanar flat end sur-face 72. It is not necessary, however, that the end surfacebe highly polished as is normally the case when bundles are directly abutted with each other.
The transparent sleeve 70 is formed on the pin 38 by dipping the pin in a suitable liquid compound to form a thin liquid film thereon and then allowing the film to cure to form a thin, smooth transparent coating. The coating should have an index of refraction matching that of the fibers in the bundle 34. Preferably a clear silicone rubber is utilized to form the sleeve although other materials could be used if they have a matching index. A suitable compound is a clear two-part silicone rubber known in the trade as a TRV compound. It will i()5~04 E. A, Landg~en 2 be appreciated that the transparent sleeve or coating formed in this manner will have a closed end 74 extending over the end surface 72, providing an optical window for the fiber bundle 34. The coating will be bonded to the ends of the fibers and thus will fill any irregularities in the fiber ends.
In addition, the coating will adhere to the epoxy cement between the fibers in the bund;e and will fill any voids that might exist at the end of the bundle. Thus, the smooth coating will in effect provide an optically polished end for the fiber bundle, thus not requiring the bundle to be highl~ polished.
The sleeve 70 also provides a protective spacer which assures that the fiber bundle face will not abut against the opposed fiber bundle face at the end of the cable 26 when the cables 18 and 26 are mated in abutting relationship as illus-trated in Fig. 2 upon interengagement of the connector members12 and 14. It will be appreciated that as a practical matter only one of the fiber optic cables of the aligned pair of cables 18, 26 need be provided with a protective sleeve since one will assure spacing between the end faces of the fiber bundles in the cables. Nevertheless, it is preferred that all the cables in the connector be provided with a protective sleeve 70.
It is desirable that the thickness of the closed end 72 of the coating or sleeve 70 be as small as possible. Typi-cally, the thickness of the sleeve is less than the thicknessof the wall of the end of termination pin 38. To maintain optical power losses below about 0.2 dB due to the spacing between the ends of the fiber bundles, it is preferred that the thickness of the sleeve be no greater than about .002 inch, which will result in a .004 inch gap between the end faces of the bundles.

E. A. Landgreen 2 1()5'~0~
While the gap between the bundles does result in a loss in optical transmission through the connector, this loss is substantially less than that which normally occurs due to the scratching of the end surfaces of the bundles, which may amount to 2 dB or more. The effect of having the protective sleeve to reduce optical losses becomes more significant when the amount of in-field use of the connector increases where the fiber bundles would otherwise be subjected to greater scratching particularly when grit is present, resulting in excessive light diffusion.
Reference is now made to Fig. 4 of the drawings which shows a modification of the forward end of the fiber optic cable of the present invention. This cable differs from that already des-cribed in that the end of the fiber bundle 34 extends beyond the end of termination pin 38'. A relatively hard, transparent sleeve 70' molded of matched indes material is pressed over the end of the bundle. The sleeve 70' includes an outwardly extending flange 76' which is positioned behind a shoulder 78' on the pin to retain the sleeve over the bundle. A suitable material for the sleeve 70' is a polycarbonate sold under the trademark Lexan by General Electric.
The closed end 74' of the sleeve 70' is flat and abuts against the planar end surface 72' of the fiber bundle. The molded sleeve 70' functions in the same manner as the coating 70 described previously herein.
While the invention has been described in connection with a fiber optic bundle containing a plurality of fibers, it will be appreciated that the protective sleeve could be provided on a single fiber, if desired.
The present invention not only assuresthat light transmission losses will be minimi~ed when the connector of the present invention is .

~5~4 E. ~. Land~reen 2 usecl in typical field environments, where abrasion of the face!s of the fiber bundles would otherwise occur due to dust or grit, the invention also provides protection for the fiber bundle ends when the cables are being shipped or handled during assembly.

TLP:mlb

Claims

WHAT IS CLAIMED IS:

1. A fiber optic cable for use in a fiber optic connector comprising:
a fiber optic bundle including a plurality of light transmitting fibers terminating in a planar end surface;
a transparent integral sleeve surrounding an end of said bundle;
one end of said sleeve being closed and overlying said planar end surface of said bundle providing an optical window for said bundle; and said sleeve having an index of refraction substantially matching that of said fibers.

2. A fiber optic cable as set forth in claim 1 wherein:
said sleeve comprises a continuous coating of pliable material.

3. A fiber optic cable as set forth in claim 2 wherein:
said coating is formed of silicone rubber.

4. A fiber optic cable as set forth in claim 1 wherein:
said sleeve is a relatively hard molded piece pressed over said bundle end.

5. A fiber optic cable as set forth in claim 4 wherein:
the inside of said end of said sleeve is flat.

6. A fiber optic cable as set forth in claim 2 wherein:
an epoxy cement fills any voids between said fibers in said bundle at said end of said bundle; and said end of said sleeve is bonded to said fibers at said planar end surface and also is integral with said cement whereby said end of said bundle is essentially free of any voids.

7. A fiber optic cable as set forth in claim 1 wherein:
a hollow contact body surrounds said bundle end, said body having one end coplanar with said bundle end surface; and said sleeve comprises a coating of pliable material on said contact body and said bundle end surface.

8. A fiber optic cable for use in a fiber optic con-nector comprising:
an optical fiber terminatng a planar end surface;
a transparent integral sleeve surrounding an end of said fiber;
one end of said sleeve being closed and overlying said planar end surface of said fiber providing an optical window therefor; and said sleeve having an index of refraction substantially matching that of said fiber.

9. A fiber optic cable as set forth in claim 8 wherein:
said sleeve comprises a continuous coating of pliable material.

10. A fiber optic connector for joining the ends of a pair of fiber optic bundles comprising:
first and second fiber optic cables each containing a fiber optic bundle including a plurality of light transmitting fibers terminating in a planar end surface, said cable bundles having facing ends;
first and second mating connector members containing said first and second cables, respectively;
each said cable including a transparent integral sleeve surrounding said end of its respective bundle;
said sleeve of each said cable having a closed end overlying said planar end surface of its respective bundle pro-viding an optical window therefor;
said sleeves each having an indes of refraction sub-stantially matching that of its respective fibers; and means in said connector members positioning said cables in axial alignment and causing said ends of said sleeves to abut each other when said connector members are mated whereby said planar end surfaces of said bundles are axially spaced apart.