Optical fiber retention mechanism for securing optical fiber cable

A fiber cable retention mechanism for securing an optical fiber cable to an optical fiber connector includes a sleeve assembly having a longitudinal axis. The sleeve assembly has an inner passageway which is disposed along the axis and sized to receive the cable connecting end of the connector. The assembly is further sized to securely receive at least a portion of the cable between the assembly and the cable connecting end.

CROSS-REFERENCE TO RELATED APPLICATION 
This application discloses subject matter which is disclosed and claimed in 
our copending and commonly assigned U.S. patent application Ser. No. 
07/816,743 filing date Jan. 2, 1992, filed concurrently herewith and 
entitled "Fiber Optic Connector." 
BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention pertains to fiber optic connectors for use in optical fiber 
signal transmission systems. More particularly, this invention pertains to 
a retention mechanism for securing an optical fiber cable to a connecting 
end of an optical fiber connector. 
2. Description of the Prior Art 
Optical fiber connectors are used to couple optically one optical fiber to 
another optical fiber or to an optical device. Such connectors are an 
important part of any optical fiber transmission system and the industry 
has expended substantial effort in their development. A commonly available 
optical connector is referred to as an ST connector (ST is a registered 
trademark of AT&T). An example of a type of an ST connector is shown in 
U.S. Pat. No. 4,812,009 dated Mar. 14, 1989. 
In installation and use, an optical fiber connector experiences disruptive 
forces from time to time. For example, axial loads may be applied to a 
connector. The axial load may result from a person inadvertently pulling 
on a cable which is attached to the connector. It is necessary to provide 
a retention mechanism for securely fastening a fiber cable to the 
connector end of an optical fiber connector. 
SUMMARY OF THE INVENTION 
According to a preferred embodiment of the present invention, a fiber cable 
retention mechanism is disclosed for securing an optical fiber cable to a 
cable connecting end of an optical fiber connector. The retention 
mechanism includes a sleeve assembly having a longitudinal axis and 
defining an inner passageway disposed along the axis. The inner passageway 
is sized to receive the connecting end. Further, the inner passageway is 
sized to securely receive at least a portion of the cable between the 
assembly and the connecting end. 
BRIEF DESCRIPTION OF THE DRAWINGS 
FIG. 1 is an exploded perspective view of a connector including a retention 
mechanism according to the present invention; 
FIG. 2 is a perspective assembled view of the connector of FIG. 1; 
FIG. 3 is a cross sectional view taken along a longitudinal axis of the 
connector assembly of FIG. 1; 
FIG. 4 is a top plan view of one mating half of the retention mechanism of 
the present invention; 
FIG. 5 is a side sectional view of the mating half of FIG. 4 is taken along 
line 6--6; 
FIG. 6 is a perspective view of the mating half of FIG. 4; and 
FIG. 7 is a view taken along line 7--7 of FIG. 4.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring now to the drawing figures in which similar elements are numbered 
identically throughout, a description of the preferred embodiment of the 
present invention will now be provided. 
With initial reference to FIG. 3, a connector assembly 10 is shown for 
connection to an adapter (not shown). The adapter is commercially 
available and includes two BNC connector ends. Such an adapter is shown in 
U.S. Pat. No. 4,812,009 (item 90 in FIG. 2). 
The connector 10 is shown in exploded perspective format in FIG. 1. The 
connector 10 includes a nut coupling 16, a ferrule 18 and a hub 20. 
Connector 10 also includes a barrel or housing 22, a retaining shell 24 
and a retention mechanism or retaining clip 26 in the form of mating 
halves 28,30. Finally, a strain relief boot 32 is provided to give strain 
relief to a cable 34 secured to connector 10. An inner spring 36 and an 
outer spring 38 are provided to complete the construction of connector 
assembly 10. 
With reference now to FIG. 3, the connector 10 is shown in longitudinal 
cross section extending from a cable entrance end 40 to an opposite or 
termination end 45. 
The ferrule 18 is cylindrical and includes an axially extending bore 44 
extending through ferrule 18. Hub 20 is also cylindrical and has an 
axially extending bore 46. The hub 20 includes an attachment end 48 at 
which bore 46 is enlarged such that ferrule 18 may be press fit within hub 
20 and with ferrule bore 44 axially aligned with hub bore 46. The hub 20 
has an exterior diameter which is reduced in dimension at an intermediate 
location. The reduced diameter portion results in the definition of an 
annular wall 52 facing the cable entrance end 40. 
The barrel or housing 22 is also generally cylindrical and includes an 
axially bore 54 extending therethrough. Axial bore 54 is sized to receive 
the ferrule 18 and hub 20 to permit the ferrule 18 and hub 20 to axially 
slidable within bore 54. A key 56 is disposed on the exterior surface of 
housing 22. The key 56 aligns with a keyway of an adapter (not shown). An 
annular ring 58 is provided on an intermediate portion of housing 22. An 
end of housing 22 opposing cable entrance end 40 is provided with external 
threads 60. 
The retaining shell 24 has a hub portion 64 with internal threads 66 sized 
to be received on external threads 60 of barrel housing 22. The retaining 
shell 24 also has an interior axial bore 68. Bore 68 is aligned with bores 
46 and 44 when threads 66 are threadially engaging threads 60 as shown in 
FIG. 3. 
Spaced from hub 64, an annular ring 70 surrounds shell 24. Shell 24 has a 
grooved surface 72 which extends from ring 70 to a terminal end 74. 
The internal spring 36 is provided surrounding hub 20 and having a first 
end 36a abutting surface 52. A second end 36b abuts an annular wall 65 of 
hub 64. As hub 64 is threaded onto thread 60, spring 36 is partially 
compressed to urge hub 20 and ferrule 18 away from cable entrance end 40. 
A nut 16 surrounds the housing 22. The nut 16 is similar to item 72 in the 
aforementioned U.S. Pat. No. 4,812,009. Hub 16 includes a groove 88 to 
permit attachment to BNC pins of an adapter (not shown). It will be 
appreciated that nuts such as nut 16 for adaption to a BNC connector form 
no part of this invention per se. The nut 16 includes an inwardly 
projecting radial flange 17. External spring 38 is disposed between ring 
58 and flange 17. 
The strain relief boot 32 has a bore 96 sized to receive cable 34. The boot 
terminates at an inner end 98 sized to be received over ring 70 and 
captured on ring 70. 
The cable 34 is a common commercially available fiber optic cable. The 
cable includes an outer jacket 100 and an optical fiber 84. Kevlar fibrous 
reinforcement 35 surrounds the fiber 84 with the jacket 100 surrounding 
the fibers 35. The fibers are yarn-like strength members. 
The retaining shell 24 has a cable connecting end 102 having a plurality of 
annular grooves formed therein. The shell 24 terminates at an enlargement 
74. 
The retaining clip 26 includes first and second mating halves 28,30. The 
halves 28,30 are snap fit together by cooperating male and female snapping 
locks 76,77, respectively. Mating half 28 is shown in FIGS. 4 through 7. 
It will be appreciated that mating half 30 is substantially identical. 
Accordingly, a description of half 28 will suffice as a description of 
mating half 30. 
The mating half 28 is generally semi-cylindrical and includes an arcuate 
inner surface 108. The mating half 28 includes a first portion 110 and a 
second portion 112 divided by a channel 114. The channel 114 is so 
disposed such that the halves 28,30 may be joined together with 
enlargement 74 received within channel 114 (as shown in FIG. 3). The inner 
surface 108 is sized such that when mating halves 28,30 are joined 
together by snap fit of male and female fasteners 76,77, shell 24 is 
received within first half 110. First half 110 includes inwardly 
projecting annular ribs in the form of arcuate rib segments 116. The 
arcuate rib sections 116 are sized to extend into the annular grooves 104 
when retention mechanism 26 is snap fit onto shell 24. 
Second portion 112 also includes arcuate rib segments 118 as well as 
inwardly protruding gripping members 120. The ribs 118 and gripping 
members 120 are sized to protrude into the flexible jacket 100 of cable 34 
when a cable 34 is received within mechanism 26 and disposed between 
portions 112 of halves 28,30. The gripping members 120 also protrude into 
the sheath material of jacket 100 to securely capture and affix the sheath 
100 to member 24. Also, the Kevlar fibers extend between member 24 and 
first portions 110. Accordingly, ribs 116 force the Kevlar fibers into 
grooves 104 to securely affix the Kevlar reinforcement fibers to member 
24. As a result, both the jacket 100 and the Kevlar fibers 35 are 
separately and independently affixed to the retaining shell 24. 
The ribs 116,118 may be sized differently to accommodate different 
materials and gripping requirements for the sheathing 100 and the Kevlar 
35. An alternative embodiment of the design is to have the ribs 118,116 
identically sized and to omit the requirement of the gripping member 120. 
With such a design, mating halves 28,30 may be completely interchangeable 
and rotatable relative to one another before snapping the halves 28,30 
together. This provides for ease of assembly. 
The foregoing detailed description of the present invention has been shown 
how the objects of the invention have been attained in a preferred manner. 
However, modifications and equivalents of the disclosed concepts are 
intended to be included within the scope of the present invention.