NO773429L - MULTI-CHANNEL CONNECTOR FOR FIBER OPTIC CABLES - Google Patents

Description

Multi-channel coupling piece

for fiber optic cables

The invention relates to connecting pieces and in particular a contact device for fiber optic cable pieces which provides improved and more complete coupling of light between the cable pieces.

In recent years, fiber optic light transmission systems in which a single optically conductive fiber or a plurality of parallel optically conductive fibers are arranged to form a flexible optically conductive cable bundle for transmitting light from one location to another have come into increasing use, not only for providing lighting but also for transferring data from one place to another. In the latter application, a light source at one end of the cable bundle is modulated with data to be transmitted,

and the data is re-acquired at the other end of the cable bundle by means of a light-sensitive detector. As the data is transported by a medium that is not exposed to radio frequency interference or detection, such light transmission systems are particularly well-suited for high security applications, such as occur in the data processing area and the military communications area.

With the increasing use of fiber optic systems, a need has developed for a connector for connecting sections or pieces of light-conducting cable bundles with minimal damage to the optical transmission path. Previously known coupling pieces for this purpose have not been completely satisfactory, especially where frequent connections and disconnections must be carried out under unfavorable environmental conditions, or where several fiber optic circuits must be connected together in a single coupling piece due to the difficulty of maintaining an accurate, completed alignment between the ends of interconnected cable pieces under such conditions. The present invention is directed to a connector or contact device which provides more accurate and complete alignment of the termination or terminal ends of fiber optic cable bundles under these conditions.

It is thus a general purpose of the invention to provide a new and improved contact device for light-conducting cable bundle pieces.

Another object of the invention is to provide a connection device for light-conducting cable bundle pieces.

Another object of the invention is to provide a connection device for light-conducting cable bundle pieces which achieves improved and more complete alignment between the ends of such pieces.

Another object of the invention is to provide a new

and improved contact means for interconnecting multiple pairs of light-conducting cable bundles with improved efficiency and completeness...

A further object of the invention is to provide

a contact device for light-conducting cable bundle pieces where secure alignment of corresponding pieces to be connected is achieved.

The invention is directed to a connector assembly or contact device for connecting the termination or terminal ends of first and second pieces of light-conducting cable bundles. The contact device comprises a socket which contains a

sheath having a forward mating end and a first recess extending rearwardly from the mating end. A first terminal support device containing a first insertion member is disposed in the first recess for placing the terminal ends of one of the cable bundle pieces in a forward-facing position. A plug including a jacket with a forward mating end and a second recess extending rearwardly from the mating end is provided with

a second terminal support device containing a

second insertion member disposed in the second recess for placing the terminal end of the second of the cable bundle pieces in a forward-facing position axially adjacent the first cable bundle piece terminal end. The terminal ends of the cable pieces are held with a high degree of axial, transverse and angular

proper alignment by means of an alignment device which extends between the first and second insertion parts.

The characterizing features of the present invention

is specified in the subsequent patent claims.

Further objects and advantages of the invention will appear

proceed from the subsequent detailed description with reference to the drawings, where like reference numbers denote like elements in the different figures, and where fig. 1 shows a perspective

view of a coupling piece constructed in accordance with the invention and shown in the unpaired state, fig. 2 shows a cross-sectional view of the connector part of the connector along the line 2-2 in fig. 1, fig. 3 shows a cross-sectional view of the plug part of the connector along the line 3-3 in fig. 1, fig. 4 shows a partially cut-away perspective view of a fiber optic terminal pin used in the connector for terminating the ends of light-conducting cable bundle segments, fig. 5a shows an enlarged, partially sectional side view of the connector in the unpaired state, and Fig. 5b shows an enlarged, partially sectional side view of the connector in the paired state; Fig. 6,: shows

in

a perspective view of the terminal pin in fig. 4 shown in connection with a pin removal tool, fig. 7 is an enlarged sectional view of a portion of the connector and illustrates the use of the pin removal tool for removing a terminal pin from the connector, FIG. 8 shows a perspective view of another embodiment of the coupling piece according to the invention, fig. 9 shows a cross-sectional view of the socket part of the coupling piece along the line 9-9 in fig. 8, fig. 10 shows a cross-sectional view of the molded part of the coupling piece along the line 10-10 in fig. 8, and

fig. 11 shows a partially cut-away side view of the connector

ket on fig. 8 in paired condition.

As reference is now made to the drawings, and in particular to fig. 1-3, a connector or a contact device 10 according to the invention comprises a flange-mounted socket 11 and a cable-mounted plug 12. The socket 11 could of course also be wall-mounted or cable-mounted without deviating from the invention. The socket comprises a mainly sleeve-shaped metal cover

13 with a front or mating end for the reception of

the plug 12, and a flange 14 behind the mating end for mon-

tering the socket to a wall or bulkhead (not shown). Individual segments or pieces of light-conducting fiber bundles

cable 15, for which connections are to be established using the connector, is inserted into the socket from the back.

A plug-receiving recess 16 extends rearward from the front end of the socket. An insertion assembly 17 which is placed in the jacket 13 carries the projecting ends of four fiber optic alignment sleeves 18 which form connection assemblies which are connected to respective of the light-conducting fiber bundle cable pieces-

ker 15.

The plug 12 comprises an essentially sleeve-shaped, elongated, cylindrical sheath with a front or mating end and a recess 20 which extends backwards from the front end of the plug for receiving in telescopic connection the front end of the socket sheath 13. Fiber optic cable pieces 21 with which. connections are to be provided, extend into the rear part of the connector. An essentially cylindrical insertion mon-

tas je 22, which is dimensioned for telescopic insertion into the recess 16, is arranged in the recess 20 and comprises four axially extending openings 23 in which four fiber optic female connection assemblies 24 are arranged (fig. 3). A locking ring 25 of conventional construction is concentrically positioned over the cap 19 to provide pivot lock engagement with protrusions

26 on the cover 13 when the plug and socket are brought together, on

a manner well known in the art. A number of locking wedges 27 on the side wall of the insertion assembly 22 cooperate with wedge grooves 28 which are arranged on the inner side wall of the recess 16 to ensure correct orientation between the two insertion assemblies.

Referring to fig. 4, 5a and 5b, the fiber optic cables 15 and 21 can be completely conventional in design and construction, in that they have an outer sheath 30 and an inner, light-conducting core of a single fiber or several fibers which are generally denoted by 31. The fiber core may be constructed either of glass or a suitable plastic material, such as that marketed under the trade name "Crofon" by the DuPont Company. In the latter case, each fiber in the core 31 can consist of a central thread of polymethyl methacrylate coated with a transparent polymer with a lower refractive index. The outer jacket 30 may be formed from a polyethylene resin marketed under the trade name "Alathon" by the DuPont Company.

Referring to fig. 4, the ends of each of the light-conducting cable pieces 15 and 21 are individually terminated by means of terminal tabs 32. Each of these tabs comprises a hollow,

essentially cylindrical metal housing 33 with an axially extending bore 34 in which the cable's fiber core 31 is placed. A layer of adhesive 35, such as epoxy, between the fiber core and the wall of the opening holds the core stably in place.

The end of the fiber core extends along the bore 34 of the terminal pin and is cut off substantially flush with the open end of the termination to provide a flat optical coupling surface 36.

The housing 33 of the terminal pin 32 comprises a front part with a reduced diameter and a rear part with an increased diameter, and an annular flange 37 between these two parts. The bore 34 has a corresponding front part with a reduced diameter and a corresponding rear part with an increased diameter which is united by a transition with a suitable oblique angle or taper, the sheath 30 of the fiber optic cable abutting the conical shoulder which is formed between these two parts.

Referring to fig. 5a and 5b, the insertion assembly 17 in the socket cover 13 is shown to consist of a plate or disk-shaped, surface-sealing part 40, a circumferential seal 40a, a cylindrical pin insertion part 41, a pin retaining disc 42 and a rear lead-through or protective sleeve 43 which is preferably forward -styled, of temperature-resistant, elastomeric materials, such as e.g. plastic and rubber. The flat sealing part 40 comprises four openings

44 which is arranged with four openings 45 in the insertion part 41, and<*>with four openings 46 in the retaining disc 42 and with four rib openings 47 in the protective sleeve 43, to provide four continuous, axially extending, bore-like passages

for recording the terminal pins which are connected to each of the four light-conducting cable pieces 14.

It appears that the insertion assembly 22 in the plug 12's jacket 19 comprises a cylindrical insertion part 50, a retaining disc 51 and a passage 52 (Fig. 5b). The insertion part 50 comprises an opening 53 which is aligned with an opening 54 in the retaining disc 51 and with an opening 55 in the bushing 52 to form a continuous, axially running passage for receiving the terminal pins which are connected to each of the four light-conducting chapel pieces 21.

In accordance with the invention, exact alignment is maintained between the terminal pins which are connected to the respective

tive fiber optic cables 15, and the terminal pins which are connected to the equivalent of the fiber optic cables 21, by means of sleeves 60

which are placed in the passages formed in the insertion assembly 17. The alignment sleeves, which may be formed of metal or a similar rigid material, are sealed in these openings.

The sleeves are held resiliently in place during insertion or removal of the plug 12 by means of annular flanges 61 on the outer surfaces of the sleeves. As particular reference is made to fig. 5a, the sleeve is allowed a certain springy, axial movement when mating as a result of the flange 61 being engaged in a groove 62 which is formed in the elastomeric material of the flat sealing part 40.

Thus, when the termination or terminal cable ends are brought together

but, pushes tinder 63 towards the back of the ring 37, the front of the ring 37

side rests close to the end of the sleeve, and the sleeve moves axially in a recess 45 so that equilibrium is achieved between similar forces which are connected to the other half of the paired

ede coupling pair.

The slight axial movement allows optimal alignment

of both termination ends for each channel, always maintaining proper axial separation between the faces 36. This inclination also allows the tines 63 to be freely separated from the ring 37 in the unmated state, so that the

the termination or terminal end 32 is allowed to be removed unobstructed by means of the tool 70 in fig. 6.

The terminal pin 32 which is arranged at the end of each of the

four fiber optic cables. 15, are introduced into their respective sleeve 60

from the rear, the annular flange 37 being brought into contact with the sleeve's rear edge. The sleeve's 60 inner dimensions are as follows

that the terminal pin assembly 32 is taken up tightly in this bg and kept in exact alignment in relation to this. A pair of prongs 6 3 projecting inwards from the wall of the opening 4 6 rest against the rearward facing surface of the annular flange 37 to lock the terminal pin in position and preclude axial movement thereof.

In the plug 12, the terminal pin 32 for each fiber optic cable 21 is received in respective openings 53 and 54 and locked in place by means of prongs 64 which project inwardly from the wall of the opening 54 against the rearward facing surface of the terminal pin's annular flange 37. The face of the annular flange rests against a shoulder formed on the rear surface of the insertion part 50, thereby preventing the terminal pin assembly from being pulled out during assembly or separation of the connector parts.

Since no alignment sleeve is present in the plug 12, the terminal pin assembly which is connected to the fiber optic cables 21 is not held firmly in place, but is instead free to move axially and laterally to a limited extent.

When the socket 11 and the plug 12 are connected as shown in fig. 5b, the insertion assembly 22 is inserted into the recess 16 when the cap 19 of the plug 12 is inserted into the end of the socket cap 13. This causes the four alignment sleeves 60 associated with the socket 11 to extend into respective of the openings 53 in the insertion assembly 22 in which ter -minal plug assembly 32 which is connected to the fiber optic cable 21 is arranged. As a result of this, the reduced diameter portions of the terminal pins which are connected to the cables 21 are taken up in respective sleeves 60. The resilient mounting of the terminal pins in the jacket 19 facilitates this by enabling the pins to align easily even with the sleeves approaching. When the plug and socket are fully joined, the end surfaces 36 of the two terminal pin assemblies come into close, parallel connection, but not in contact with each other, for highly efficient light transmission. Since the alignment sleeves 60 determine the positions of the terminal pins, misalignment of the cooperating, light-transmitting surfaces 36 is excluded.

When the coupling piece is completely assembled as shown in fig. 5b, also place the bushings .43 and 52, flat

the seal 40 and the circumferential seal 40a in a compression state.

As a result, the connector is completely sealed from impurities or contaminants that may be encountered in the environment where the connector is to be used.

According to another aspect of the invention, the fiber optic terminal pin assemblies 32 associated with each fiber optic cable are removed from their respective passages by inserting a small, sleeve-shaped tool 70 into the passage from the rear. In the case of the socket 11, this tool serves, as shown in

fig. 6, to compress the prongs 63 against the side wall of the opening 46, or to compress the prongs 64 against the side wall of the opening 54 in the case of the plug 12, with the result that the pin assemblies are released and can be removed in a rearward direction from the connector parts. This is a significant advantage as it enables individual fiber optic pins to be removed, e.g. by correcting

sion of installation errors or replacement of damaged coupling pieces or parts thereof.

An alternative arrangement for maintaining alignment between terminal lugs in a sheath type connector is shown in fig. 8-11. In this embodiment, a socket 80 is provided with an elongated cover 81 which delimits a recess

ning 82 in which is placed an insertion assembly 83 with four countersunk fiber optic terminal pin assemblies 32. The receptacle 80 is adapted to mate with a plug

84 with an elongated sheath 85 which delimits a recess 86

in which four further terminal pin assemblies 32 are countersunk mounted. The cover 85 of the plug 84 is dimensioned so that it extends in a telescopic connection over the plug receptacle

end part of the jacket 81. Insert assemblies 87 and 88 of similar design to those provided in the socket 11 and the plug 12", are provided in the socket 80 and the plug 84 to hold the fiber optic terminal pin assemblies in position.

As the terminal plug assemblies 32 are arranged with their coupling surface 36 parallel to the uncovered surfaces of the lead-in assemblies, the coupling flanges for corresponding terminal pins are brought into close adjacent connection when the coupling piece parts are brought together as shown in fig. 11. In order to maintain the precise alignment required between the coupling rafts 36 to achieve good efficiency, the socket insertion assembly includes five axially extending alignment pins 90 which stretch

fits into each of five alignment sockets 91 which are arranged in the surface of the plug 84 insertion assembly 88.

By sizing these elements for tight but non-binding engagement, the surfaces of the two lead assemblies are maintained in precise alignment at all times during their mating, regardless of movement of one or the other lead assembly relative to its sheath.

It will be appreciated that although the invention has been shown in connection with coupling pieces having round caps and four connecting connections, it is also possible to adapt the invention r connection with a greater or smaller number of connections, and with caps having other shapes and sizes, including rectangular and square cross sections.

Claims (12)

1. Connector assembly for connecting the terminal ends of first and second optical fiber cable pieces, characterized in that it comprises a socket containing a jacket with a forward mating end and a first recess extending rearwardly from the mating end, a first terminal support device containing a first insertion part disposed therein first recess for placing the terminal end of one of the cable pieces in a forward facing position, a plug containing a jacket having a front mating end and a second recess extending rearwardly from the mating end, a second terminal support device containing a second insertion member disposed in the second recess for placing the terminal end of the second of the cable pieces in a forward-facing position axially adjacent to the first ... the terminal end of the cable piece, and an alignment device extending between the first and second insertion parts to keep the terminal ends of the cable pieces laterally aligned. 2. Connector assembly according to claim 1, characterized in that the alignment device comprises a sleeve in which the terminal ends of the cable pieces are slidably engaged. 3. Connector assembly according to claim 2, characterized in that the first and second terminal support devices each comprise an essentially sleeve-shaped terminal pin assembly which is placed over the end of each of the terminal ends, and that the pin assemblies are slidably engaged at opposite ends of the alignment sleeve. 4. Connector assembly according to claim 3, characterized in that one of the terminal pins and the corresponding end of the alignment sleeve is resiliently arranged in the first insertion part, and the other of the terminal pins is resiliently mounted by means of the respective terminal support device the nings. 5. Connector assembly according to claim 2, characterized in that the first and second terminal support devices each comprise axially aligned openings, that one end of the alignment sleeve extends into one of the openings and is resiliently mounted to its associated terminal support device, and that the other end of the aligning sleeve extends into the other of the openings and is slidably engaged therein. 6. Connector assembly according to claim 1, characterized in that at least one of the terminal support devices comprises an essentially sleeve-shaped terminal pin assembly which is placed over the end of the respective one of the terminal ends, and that the terminal support device comprises an axially extending recess for sliding reception of the terminal pin.• 7. Connector assembly according to claim 6, characterized in that the terminal support device comprises a holding device for locking the terminal pin assembly in the axially extending recess. 8. Coupling piece assembly according to claim 7, characterized in that the holding device comprises springy fingers which are placed in the side wall of the axially extending opening, the fingers being displaceable from the rear of said opening (to release the terminal pin assembly. 9. Coupling piece assembly according to claim 1, characterized in that the alignment devices comprise at least one axially extending alignment pin which is placed on one of the insertion parts, and a complementary dimensioned and aligned pin receiving base on the other of the insertion parts. 10. Connector assembly according to claim 9, characterized in that the terminal ends lie mainly flush with the forward-facing surfaces of each of the insertion parts. 11. Connector assembly according to claim 1, characterized in that it comprises a wedge device for orientation of the terminal ends in the socket and the plug in a predetermined relationship. 12. Coupling piece assembly according to claim 11, characterized in that the wedge device comprises a number of wedge grooves in the aforementioned first recess and a corresponding number of guide wedges on the aforementioned second insertion part.