CA1133296A - Retainer for terminal in a fiber optic connector - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE

The present invention is directed to a fiber optic cable connector assembly and more particularly to fiber optic cable connectors which, when mated, form an assembly which accurately aligns and spaces the terminal ends of one or more fiber optic pairs, Fiber optic con-nector assemblies must properly align and closely space the terminal ends of the optical fiber pairs to very exact tolerances, Fiber optic connectors have generally included terminating pins constructed from rigid material which re-ceive the optic fibers and support them in the connector, In many cases, damage to the pins or other connector com-ponents result during servicing, The connector assembly of the present invention includes a connector having a cable terminating tubular pin which receives one of the cables and which also has an outer circumferential flange. The pin is received within a channel of the connector body which channel has a forwardly facing annular shoulder portion.
A cylindrical retainer coaxially disposed about the pin has a rear surface engaging the channel shoulder and forwardly depending fingers engaging the pin flange. The rearward end of the retainer also includes an integral spring mechan-ism which urges the pin in the forward direction so that its forward end continuously engages a spacer within a mating connector which causes the terminal ends of the coupled cables to be closely and controllably spaced for efficient light transfer between the fiber optic cables. This assembly allows ease of manufacture and facilitates disassembly of the connectors during servicing.

Description

` " ~;~6 The present invention is generally directed to a fiber optic cable connector assembly and more particularly to fiber optic cable connectors which, when mated, form an assembly which accurately aligns and spaces the terminal ends of one or more fiber optic pairs to couple the optical fibers of the cables together for efficient light transfer.
The virtues and advantages of fiber optics in today's technology are well known and therefore need not be alluded to herein. With the ever increasing use of fiber optics, the need for efficient and readily usable and service-able fiber optic connector assemblies has arisen Fiber optic connector assemblies for optically coupling the terminal ends of fiber optic cable pairs to-- gether must properly align and closely space the terminal - ends of the optical fiber pairs to achieve efficient, low cost, light trans~er between the cables. Moreover, while the terminal ends are spaced closely apart, they must not be allowed to touch. Any touching of the fiber ends could re-sult in scratching of the finely polished terminal end sur-faces and consequent decrease in light transfer efficiency.
Hence, the terminal ends of fiber optic cables must be aligned and spaced to very exact tolerances, and even more so~ when the cables are of the single fiber variety.
Whenever it is required that connector components be fabricated to closely held tolerances, manufacturing costs rise making the connectors exhorbitantly expensive. Such has been the case with prior art connectors.
As with any type of connector interconnection, field service may become necessary When field service is required, it is advantageous, for obvious reasons, if the interconnection can be easily disassembled without dest oying any of the connector component parts or damaging the compon-.

~33'~96 ent parts to the extent that they cannot be re-used, Fiber optic connectors have generally included terminating pins constructed from rigid material which receive the optic fibers and support them in the connector, When service is required, it is usually necessary to remove the terminal pins, Unfortunately, the fiber optic connectors which have : come heretofore have included mechanisms for accurately positioning the terminating pins within the connectors which impede the e~traction of the terminating pins, Hence, in many cases, damage to the pins or other connector components result during servicing.
It is therefore a general object of the present invention to provide improved connectors for a fiber optic connector assembly, It is a more specific object of the present inven-- tion to provide a fiber optic connector which includes im-proved optical fiber terminal end alignment and spacing means to achieve efficient light transfer, . The invention provides a fiber optic connector for use in a fiber optic connector assembly of the type which includes alignment means and stop means for aligning and closely spacing the forward ends of the optical fibers . of at least one pair of fiber optic cables to thereby opti-cally couple the fiber optic cables together for efficient light transfer, The connector comprises a rigid terminating ; member having a longitudinal bore dimensioned for receiving :~ the forward end of one of the cables and having an outer engageable portion, a channel having an inner surface dimen-sioned for receiving the rigid member and having an interen-gageable portion, and retainer means disposed between the channel inner sur~ace and the rigid member, The retainer means includes a forward end portion communicating wit~ the . -2-rigid melllher outcr cng~gc.lble l)ortion alld a le.lr l~ortion - communiccltillg with the channel inner surface el~gageable portiol3.The rear portion of the retainer means inclu~es integral sl)rin~
mealls for urging the rigid me]nber in the forw~rd axial directio against the connector assembly stop means to cause the forward end of the rigid me]nber to be in continuous enBagement with the stop means.
The present invention also provides a fiber optic connector for use in a fiber optic connector ~ssembly which aligns and closely spaces the forward ends of the optical fibers of at least one pair of fiber otpic cables to thereby optically couple the fiber optic cables together for e~ficient light transfer. The connector includes a rigid body having a channel therethrough, an alignment sleeve within the channel having an inner abutment means intermediate the ends of the sleeve and an interlocking protrusion at the rear end of the sleeve and a rigid terminating member within the sleeve having a longitudinal bore dimensioned for receiving the forward end of one of the r cables and having an outer surface indentation communicating with the alignment sleeve locking protrusion for locking the sleeve and the terminating member together. The terminating member also includes a front end abutting the sleeve abutment means for accurately and closely spacing the forward end of the optical fiber of the fiber optic cable within the longitudinal bore with the forward end of an optical fiber carried within - the terminating member of a mating connector which also abuts the abutment means.
The invention is particularly directed toward a retainer member for retaining a terminating mcmber within a fiber optic connector against rearward movement and urging tlle terminating member forward within the fiber o~)tic connector.
The retainer member comprises a forward end portion having a .~

il33Z96 plllrillity of tincs cooperatively enga~ing the tclilliniltillg : member and a rearward end ~ortion having integral rcsi]icnt means rearward of the tines cooperatively engaging the fiber optic connector.
The features of the present invention which are believed to be novel are set forth with particularity in the appended claims. The invention, together with further objccts and advantages thereof, may best be understood by : -3a-reference to the following description taken in connection with the accompanying drawings, in the several figures of which like reference numerals identify like elements, and in which:
Figure 1 is a partial cross-sectional view with portions cut away showing a fiber optic connector assembly incorporating fiber optic connectors embodying ~he present invention to an enlarged scale;
Figure 2 is a side plan view with a portion broken away of a principal component of the fiber optic connector of the present invention which embodies the present inven-tion; and . Figure 3 is a cross-sectional view of another .~
principal component of the fiber optic connector of the present invention which embodies the present invention, Referring now to Figure 1, it shows a partial cross-section of a con~ector assembly embodying the present invention and more particularly shows in cross-section the structure associated with optically coupling one pair of fiber optic cables. In actual practice, the connector as-sembly may include additional structure for optically coup-ling a plurality of fiber optic cable pairs, The connector assembly 10 of Figure 1 includes a plug connector 11 and a receptacle connector 12. The plug connector 11 comprises a generally cylindrical outer shell 13, a rigid body comprising a forward section 14 and a rear section 15, a rear grommet 16, and a fact seal 19. The plug connector 11 also includes a fiber optic cable termina-` ting pin assembly 17 and a retainer 18 for the terminating pin assembly 17.
The receptacle connector 12 includes an outercylindrical shell 20, a bayonet ring 21, and a rigid body 1133~

comprising a forward section 22 and a rearward section 23 The receptacle connector 12 also includes a fiber optic cable terminating pin assembly 24 and an alignment sleeve 25.
Referring more particularly to the plug connector 11, the outer shell 13, which is formed from aluminum, for example, includes at its rear end an external thread 30 to accommodate accessory mounting structure or coupling devices (not shown). The outer shell 13 has a forward extension 31 which extends beyond the face seal 19 of the connector in the forurard direction and carries a plurality of bayonet pins one of which is shown at 32.
In a similar manner, the receptacle connector 12 includes an external thread 33 at its rear end and a forward extension 34 which includes a plurality of alignment flanges 35 which are received within alignment slots 36 of the for-ward e~tension 31 of the outer plug connector shell 13. The bayonet ring 21 is retained on the outer periphery of shell 20 by retention ring 37 and an annular ~lange 38 of shell 20.
Between retention ring 37 and annular flange 38 is a washer 39. As the plug and receptacle connectors mate and the bay-onet ring 20 is rotated, its ramped surface 40 acts upon the bayonet pin 32 to cause the two connectors to be pulled to-gether into full mating relation.
Referring again to the plug connector 11, the terminating pin assembly 17 comprises a rigid terminating .1 ' member taking the form of a generally cylindrical pin having a forward extension 50 of minor diameter and a rear portion 51 of major diameter. Portion 51 includes a circumferential flange 52 forming a rearwardly facing shoulder portion 53 which may also be described as an outer engageable portion.

The terminating pin assembly 17 also includes a plurality o~
axial slots 54 which terminate in forward curved portions 55.

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The entire terminating pin assembly 17 includes a longitudi-nal bore 56 which is dimensioned for receiving the one or more optical fibers 60 of the fiber optic cable 61 Fiber optic cable 61 also includes an annular layer of protective material 62, a plurality of coaxial strength members 63, and - an outer sheath 64.
The one or more optical fibers 60 extend through the longitudinal bore of the terminating pin assembly 17 in the forward direction and terminate at the terminal end face of the pin assembly at 57.
In terminating the fiber optic cable 61 with the terminating pin assembly 17, the annular protective layer 62 is removed so that the one or more optical fibers 60 extend through the longitudinal bore 5.6 of the terminating pin and beyond the terminal end face 57 of the pin Thereafter a suitable adhesive such as epoxy may be introduced into the forward end of the pin to secure the optical fibers at the pin forward end. Thereafter, the optical fibers are ground and polished to a smooth surface within the plane of the terminal end 57. Also, the strength members 63 are received within the axial slot 54 and layed within the forward curved portions 55 of the slots Thereafter, the strength members 63 are epoxied in the curved portions and a ring-shaped retaining member such as a split ring ferrule 5~ is crimped over the strength members in the curved portions 55 to ~ securely terminate the fiber optic cable 61 within the pin assembly.
.. The grommet 16 includes an aperture 59 for each :; fiber optic cable 61 and provides a t~ght moisture seal ,'! 30 therewith.
The rigid body portion 14 includes a first bore 17 dimensioned to accommodate the major diameter section 51 ' . ~ ~

~33296 of the terminating pin and a second bore 71 which is dimen-sio~ed to allow the forward extension 50 of the pin to extend therethrough, The rigid body portion 15 includes a first bore 72 and a counterbore 73 forming a forwardly facing shoulder 74 which may be described as an inner engageable portion. Also, the bores 71, 70, 72 and 73 communicate wi,th one another to form a channel for receiving the terminating pin assembly 17.
The retainer 18 is of generally cylindrical con-struction and is dimensioned to be received within the counter-bore 73. The rear end 80 of the retainer is in abutment against the forwardly facing shoulder 74 of counterbore 73 and includes at its forward end a plurality of axial slots which form forwardly extending fingers 81 which are bent towards the axis of the retainer and communicate with the rearwardly facing shoulder 53 o~ flange 52 of the terminatiDg pin assembly 17. The retainer 18 is shown in greater detail -,,,.~
~, in Figure 2. As can be seen in Figure 2, the retainer in-cludes the rearward portion 80 and the axial slots 82 with the bent finger portions 81 which depend towards the axis ~' of the retainer in the forward direction. At the rearward end of the retainer, the retainer also includes a plurality ",.
,; of slotted portions 83 which are axially and angularly I ' spaced. In this preferred embodiment, the slots are angu~
` larly spaced by approximately 90. As can be seen, the r~ slots extend into the retainer substantially normal to the '~ axis of the retainer and thereby i~orm at the rearward end of the retainer an integral spring means.
~, Referring again to Figure 1, it can be seen that :
, 30 with the retainer coaxially disposed about the terminating `,~r pin assembly 17 and communicating at its rearward end with the forwardly facing shoulder 74 o~ counterbore 73 and . , : ~ , communicating with the rearwardly facing shoulder 53 of flange 52 of the terminating pin assembly 17, the retainer retains the terminating pin assembly for rearward movement.
Also, the integral spring means formed by the slots 83 causes th~ retainer to urge the pin assembly 17 in the for-ward direction so that the terminal end face 57 is in con-- tinuous abutment with a spacer 90 carried by the mating receptacle connector.
As can be seen from Figure 1, the retainer provides the resilient urging of the pin assembly in the forward direction without blocking the gap between the terminating pin and the inner surface of the channel formed by the bores 72 and 73. As a result, it is a simple manner to extract the cable and terminating pin assembly by simply introducing an appropriate tool which causes the tines or fingers 81 to be displaced for releasing the flange 52.
Thereafter, the pin assembly can be easily removed. As a result, the receptacle connector 11 is readily field service-able, Inasmuch as there are no alignment components blocking !~
access of the pin removal tool to the pin retaining mechan-, isms, damage to any of the component parts of the connector during removal of the pin assembly upon servicing is sub-stantially precluded.
Referring now to the receptacle connector 12 of Figure 1, the terminating pin assembly 24 is formed in the ; shape of a hollow cylindrical pin and includes a forwardly extending minor diameter portio~ 100 and a rearward major diameter portion 101. The major diameter portion 101 in-cludes a circumferential flange 102 which has a rearwardly facing shoulder portion 103. The rear rigid body portion 23 includes a bore 105 having depending fingers or tines - 106 which communicate with the rearwardly facing shoulder portion 103 o~ flange 102 for retaining the pin assembly 24 ; within the connector, The forward rigid body portion 22 includes a bore 110 which is dimensioned for receiving the alignment sleeve 25. The alignment sleeve 25 is shown in greater detail in Figure 3. The alignment sleeve 25 is generally cylindrical iD shape and is formed from a resilient material such as Teflon* or a suitable plastic. It includes a rear bore 111 and a forward bore 112 which are separated by the peripheral inner flange 90 which forms a spacer or stop means between the bores. The rear bore 111 includes an inner circumferen-tially V-shaped ridge 113 which coacts with a V-shaped cir-,~ cumferential notch 107 of the forward pin extension 100 for captivating the forward extension 100 within the rear bore 111. The flange 90 and the ridge 113 are so spaced apart that when the pin extension 100 is received within the bore 111 so that the notch 107 receives the ridge 113, the forward terminal end face 108 of the pin assembly 24 is in abutment with the rearwardly facing shoulder portion 91 of flange 90.
- At its forward end, the alignment sleeve 25 in-, cludes a plurality of axial slots 114 and a conical opening ;'`l 115, The conical opening 115 guides the mating forward end 50 of pin assembly 17 into the forward bore 112 and the slots 114 provide resilient surface contact between the bore and the pin to further secure the pin within the bore.
The terminal pin assembly 2~ includes along its entire length a longitudinal bore which is dimensioned for receiving the fiber optic cable which it terminates (not shown), Its cable also includes one or more optical fibers which are epoxied at the forward end of the pin assembly - and ground and polished to a smooth surface at the terminal *Trade Mark ~. ~33296 end face 108. Thus, when the plug and receptacle connectors are joined in the fu]ly mated relation as shown in Figure 1, the terminal end faces of the pins and thus the optical fibers will be closely and accurately spaced apart by the width dimension of the flange 90 to achieve efficient light transfer Also, the bores 111 and 112 are dimensioned for tightly receiving the forward ends of the pin assemblies and are aligned relative to one another so that the terminal ends of the pin assemblies will also be in aligned relation for effecting efficient light transfer.
The plug and receptacle connectors comprising the fiber optic connector assembly of the present invention enables accurate alignment and close spacing of the forward ends of the optical fibers which are optically coupled to-gether to achieve efficient light transfer while at the same time minimizing the number of component parts which must be manufactured to a tight tolerance. Because the retainer 18 includes the integral spring means for urging the pin as-sembly 17 in the forward direction so that its terminal end face 57 is in abutment with flange 90 of alignment sleeve 25, axial manufacturing tolerances are absorbed Also, the alignment sleeve 25 may be so dimensioned as to float within the bore 110 of rigid body portion 22 so that neither the ; bore 110 nor the outer dimension of sleeve 25 is critical.
~ The critical dimensions which must be tightly controlled are .
only the dimensions of the bores 111 and 112 of the alignment sleeve, which is a plastic or Teflon* part, and thus easily manufacturable Even these dimensions are not extremely v~
critical inasmuch as the alignment sleeve is constructed from a resilient material.
As previously mentioned, the connector assembly ` of the present invention is readily field serviceable .

*Trade Mark '~` ` 1~33~6 inasmuch as there is no alignment structure blocking access of a removal tool to the retaining fingers 81 which retain ~; the pin assembly 17 Similarly, there are no alignment : components which block access of the removal tool to the .` tines 106 which retain the pin assembly 24. As a result, the fiber optic connector assembly of the present invention may be readily field serviceable without consequent damage ` to its individual component parts.
While a particular embodiment of the invention has been shown and described, modifications may be made, and it is in$ended in the appended claims to cover all such changes and modifications which fall within the true spirit of the invention.

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Claims (4)

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:

1. A retainer member for retaining a terminating member within a fiber optic connector against rearward movement and urging said terminating member forward within said fiber optic connector comprising a forward end portion having a plurality of tines cooperatively engaging said terminating member and a rearward end portion having integral resilient means rearward of said tines cooperatively engaging said fiber optic connector.

2. A retainer member as defined in claim 1 wherein said tines are defined by a plurality of axial grooves in said forward end portion, said forward and rearward end portions together defining a hollow generally cylindrical member, said tines converging towards the longitudinal axis of said cylindrical member for engagement with said termina-ting member.

3. A retainer member as defined in claim 1 wherein said rearward end portion includes a plurality of slots, said slots lying in planes perpendicular to said terminating member and being angularly and axially spaced to define said integral resilient means.

4. A retainer member as defined in claim 3, where-in said slots are angularly and alternately spaced by sub-stantially 90°.