SE442454B - CONNECTORS - Google Patents

Description

15 20 25 30 35 '40 .7906775-7 2 expensive precision instruments, which give very low transmission losses. However, they are not designed for repeated coupling and uncoupling cycles or for maintenance by less experienced field personnel.

This is especially true for applications over longer distances, such as telephone systems and other applications that require extremely low transmission losses, where expensive connectors with low losses are not always well suited for applications that require a large number of connectors, which do not have to achieve the same low level of transmission losses. For example, in such applications as computers and other data transmission applications, a large number of optical fibers of relatively short lengths are used, which terminate with connectors, which must be suitably arranged to enable repeated interconnection-interconnection cycles for field maintenance. Thus, there is a need for a cheap, improved connector of the type described above.

Accordingly, the object of the invention is to provide a new, inexpensive, improved and detachable connector for optical fibers.

The structure of the connector according to the invention is designed to comprise cooperating features, so that the above stated purpose is fulfilled.

Thus, the invention relates to a connector for connecting one or more optical fibers to a fiber optic component or to other optical fibers, comprising a plug means with first and second, transversely mating plug portions for holding said optical fibers therebetween. According to the invention, the first plug portion comprises a front end with a continuous forward-facing surface extending in front of the second plug portion, the optical fibers extending through the front end of the first plug portion to the front surface. The plug means is arranged to be inserted into a suitable housing means with the continuous, forward-facing surface of the plug means positioned to optically couple said optical fibers to the fiber optic component or the other optical fibers. The connector further includes a locking device for holding the continuous, forward-facing surface of the plug member against the fiber optic component in a touching position. Conveniently, the locking device releasably holds the plug member in the housing member. The locking device may comprise a locking hole in one plug member or housing member and a locking bead in the housing member or other plug member for cooperating with the locking hole. Preferably, the distance between the barrier hole and the fiber optic component is less than the distance between the barrier bead and the fiber optic component, the difference between these distances being sufficient to press the continuous, forward-facing surface against the fiber optic component while the plug member is releasably held in the housing. orqanet. The connector may further comprise a restricting device for restricting insertion of the plug member into the housing member. Suitably the restriction device comprises at least one shoulder on the plug device for cooperating with the housing member. Furthermore, there is a device for preventing axial displacement between the first and second plug portions. This device may comprise at least one groove in one plug portion and at least one complementary strip in the other plug portion, the strip cooperating with the groove to prevent axial displacement between the first and second plug portions. If each plug portion has transversely mating surfaces, the connector may also be arranged so that each of the transversely mating surfaces of the plug portions is provided with grooves which together form an axial hole through the plug member when the plug portions are interconnected, the hole extends through the first plug portion to the continuous, forward-facing surface, and the optical fiber is in said hole when the plug portions are interconnected.

Each optical fiber may be arranged in a fiber optic cable, each fiber optic cable comprising an outer insulating sheath and a reinforcing element arranged inside the outer sheath, the optical fiber being arranged inside the reinforcing element and further provided with an inner insulating sheath. Furthermore, the through hole in each plug means may comprise a small diameter portion for receiving one of the optical fibers, a relatively larger diameter portion for receiving the inner insulating sheath of the optical fiber and an even larger diameter portion for receiving the optical fiber. receiving the outer insulating sheath of the fiber optic cable containing the optical fiber. The through hole further includes a conically shaped portion for receiving the reinforcing member of one of the fiber optic cables.

The housing means and the plug means may be provided with complementary angular alignment means for providing polarized coupling of the housing means and the plug means. In this case, the housing means or plug means can be provided with an axial, inner groove and the plug means or housing means be provided with a projecting strip, which can be placed axially in said grooves.

The invention is described in more detail below with reference to the accompanying drawing, in which Fig. 1 is a perspective view of the connector according to the invention for optical fibers, which is shown generally in various applications, Fig. 2 is a central longitudinal sectional view on an enlarged scale of the connector made for use in a double fiber and provided with a pair of identical, in-line, plug means in a housing, Fig. 3 is a vertical cross-sectional view through Fig. 2, a part of the plug means being removed and ,, ._____....._.... ..__.....-. ~ .__....._. &> LW 79067'ï5-7 shown separately to clarify the view, Fig. 4 is a vertical sectional view taken substantially along line 4-4 in Fig. 2, Fig. 5 is a vertical sectional view taken substantially along line 5. Fig. 2 is a vertical sectional view taken substantially along line 6-6 of Fig. 2, and Fig. 7 is an end view taken substantially in the direction of arrow 7-7 of Fig. 2. the optical cable being shown in cross section.

In the drawing figures, the same reference numerals indicate the same elements.

The drawing shows an optically detachable optical fiber connector according to the invention, designated 10 in order to provide in-line interconnection, the connector being shown with its widest application for interconnecting a pair of optical fibers or a single optical fiber and a light source or a detector. As can be seen from the drawing, the fiber optic cable used in connection with the invention is a 4 duplex cable 12. However, as shown in the lower right corner of Fig. 1, the fiber optic cable may be a simple cable 14 for use with a connector according to the invention. As shown in Fig. 2, the duplex cable 12 has an outer insulating layer or sheath 16 of thermoplastic material. Each individual optical fiber 20 of the duplex cable 12 also has an inner insulating layer or sheath 18 of thermoplastic material. As shown in the drawing, the outer sheath 16 and the inner sheath 18 are cut so that the inner sheath sections 18 extend beyond the outer sheath 16 and the optical fibers 20 extend past the corresponding inner sheath sections 18 to form the connection end of the fiber optic cable 12. Reinforcement or stiffening elements 22 are arranged between the inner jacket sections 18 and the corresponding optical fibers 20, and are shown widening outwards in Fig. 2.

Fig. 2 shows the fiber optic connector 10 according to the invention designed for interconnecting a pair of fiber optic cables 12 in opposite line relationship. The connector 10 aligns the corresponding optical fibers 20 of the cable 12 in line to prevent low insertion losses due to lack of axial, transverse or angular alignment. However, the advantages and features of the fiber optic connector 10 according to the invention are equally applicable to connecting a single fiber optical cable 12 to a light source or a detector, which is described in more detail below.

As shown in Figs. 2-7, the fiber optic connector 10 according to the invention has one or more connection plug means, generally designated 24, depending on the application of the connection means 10. Each plug member 24 is divided in the axial direction to include a first longitudinal plug member 28, which is shown as the lower and upper plug members in Fig. 3. The plug members 26 and 28, which form a hole extending through a shown contour, extending axially through the connector plug member 24, are transversely connectable to clamp the fiber optic cable 12 and the optical fibers 20 in the through hole, as described below.

A housing 30 is arranged substantially in the form of a rectangular sleeve, which receives the plug means 24 for holding them in axial alignment and holding the split plug elements 26, 28 in an interconnecting position, in which they securely clamps the fiber optic cables l2. The outside of the plug means 24 is substantially rectangular in shape for insertion into the inner rectangular receiving opening, which extends completely through the housing 30 from end to end. The outside of the plug members 24 on their split members 26, 28 may be knurled as at 34 (shown in Fig. 3) at their outer, outwardly facing ends to facilitate gripping during insertion and removal of the plug members in the respective members. from the house.

The plug means 24 also have projections 36 which abut the ends of the housing 30 so that the connecting ends of the plug means 24, if desired, can be mounted at some distance from each other at their connecting ends, as shown at 38 in Figs. 2 and 3, to prevent scratching of the aligned optical fibers 20 when they are in the fully coupled position.

For complementary engagement with each other, locking means are provided between each of the plug means 24 and the housing 30 to releasably retain plug means in the axial direction of the housing. Fig. 3 shows the locking means comprising a bore 40 through the housing 30, which bore communicates with each of the plug means 24, and a radially projecting locking projection or bead 42 formed on the lower divided element 26 of each of the plug means, As shown in Figs. 2 and 3, the distance between the locking heel 40 in the housing 30 may be slightly less than the total distance between the center lines of the locking beads 42. When connecting a pair of plug members 24 and their resp. fiber optic cables 12 in line with each other, the shoulders 36 are located to allow the plug means 24 to be moved against each other while reducing the separation between the ends of the corresponding optical fibers 20 in the housing 30 to a minimum.

Means are provided between the plug means 24 and the housing 30 for angularly locating the components to provide polarized interconnection thereof, particularly for use with duplex cables 12 or multiple fiber bundles. More specifically, as shown in Fig. 6, an inwardly projecting axial strip 44 formed on the inside of the housing 30 and an axial groove 46 formed on the outside of the plug member 24 for receiving the strip 44 so that the plug member can be inserted into the housing only with a predetermined angular angle. direction. The groove 46 may be formed on either of the plug members 26, 28 of the plug member 24 according to the design and the desired alignment of the plug member.

As mentioned above, each plug member 24 comprises a first and a second plug element 26, 28 (the lower and the upper plug element, respectively, as shown in Fig. 3). Axial engaging means are provided between the plug members 26, 28 to prevent axial displacement therebetween. These means comprise a pair of axially extending grooves 48 (shown in Fig. 2) along the inner surface of the plug member 26 and a pair of projecting, axially extending strips 50 on the corresponding inner side of the plug member 28.

When assembling the plug elements 26, 28 for mounting on either side of a fiber optic cable 12, the plug element 26 is simply mounted in the transverse direction, the strips 50 of the plug element 28 being mounted in the groove 48 of the plug element 26 to clamp the fiber optic between the plug elements. cable l2. .-.__.._ _ _ _ .._.___.....__...__ - .. ~ ._..., __..., ........_- ...-..-_. After the plug members 24 have been assembled, they are inserted axially into the housing 30 in the manner described above. The plug member 26 of each of the plug members 24 is as shown in Fig. 3 longer than the corresponding plug member 28 and is dimensioned at its connecting end to extend over the connection end of the plug member 28 so that it has substantially the same shape and size as the inside of the housing 30; . The plug member 26 thus has a single continuous interconnecting surface 52, which extends completely over the plug member 24 at its connecting end, which is opposite the corresponding interconnecting surface 52 of the interconnected plug member 24, when as shown in Figs. 2 or 3 is fully interconnected, or which is opposite a light source or a detector, when a single plug means 24 is used. Furthermore, the non-segmented coupling surfaces 52 of the plug means 24 ensure proper interconnection of the plug means by completely eliminating a source of alignment errors that would otherwise exist. The relative dimensioning between the locking holes 40 in the housing 30 and the locking beads 42 of the plug members 24 as well as the studs 36 of the plug members 24 serves as mentioned above to effectively control any distance between the coupling surfaces 52 of the opposite plug members 24. 26 and 28, they are advantageously cut to be flush with resp. The coupling surface 52 of the plug member 24. As mentioned above, the axially extending through hole through each plug member 24 has a contour shape for receiving the components of the fiber optic cable, such as the duplex cable 12. More specifically, in the duplex cable 12, as shown in Fig. 2, the composite through hole has a small diameter portion 54 for each optical fiber 20 and a relatively larger diameter portion 56 for receiving the inner sheath 18 of each optical fiber 20. Furthermore, the composite, through hole has an even larger portion 58 for receiving the one-piece outer sheath or sheath 16 of the duplex cable l2. Furthermore, the inner surface of the portion 58 of the through hole, including the portion extending through both plug members 26, 28, is internally grooved as at 60 in Fig. 3 to promote the engagement of the plug members 24 with the duplex cable 12. As shown in Fig. 3, the through hole of each plug member 24 also has a conically shaped portion 62 formed in the plug member 28 at the junction between the portions 54 and 56 of the through hole to receive the reinforcing members 22.

The housing 30 and plug elements 26, 28 of each plug member 24 may be made of thermoplastic material to provide easy fabrication and assembly while providing a reliable, low insertion loss fiber optic connector, which connector is relatively inexpensive to manufacture. The connector and its new features can be easily adapted to a variety of different applications. For example, the connector shown in Figs. 2-7 can be used in applications for making in-line connections, which is sometimes referred to as "flying joint" 10 (Fig. 1). The connector according to Figs. 2-7 can also be used as a bulkhead or wall connector attached to a panel 72 (Fig. 11 by means of snap fingers 74, which are formed in one piece on the sides of the housing 30. The connector shown in Figs. 2-7 may also be attached to a printed circuit board 76 (7906775-7). Fig. 1) by means of projections 78, which are formed in one piece with the housing for snap fitting in heel 80 received in the circuit board 76. The connector according to Figs. 2-7 can also be used with the housing 30 manufactured as at 82 (Fig. 1) to provide an expandable section for use with several individual plug means 24.

In addition, the plug means 24 can be used in input / output type connector applications which form part of a transmitter or detector by utilizing complementary housings 84 (Fig. 1) with an interior made in the same manner as the housing 30.

With the connector according to the invention it is possible to use a divisible construction with the contours of the through hole formed in the plug means to receive the optical fiber, the inner sheath, the reinforcing elements and the outer sheath.

The reinforcing elements are held in place by being caught between the longitudinal plug elements when they are bonded together. It has been found that in addition to the conventional epoxy bonding techniques, the design of the connector is suitable for ultrasonic welding of the plug elements by selecting and using suitable thermoplastics as the material from which the element of the connector is cast. The construction of the connector makes it possible to terminate the optical fibers either by polishing the fiber ends or cutting off the fiber ends, e.g. by means of a razor blade, when plastic optical fibers are used. It has been found that the establishment of a single continuous coupling surface, which is not segmented at the connection end of the pluoo element, facilitates the termination of the optical fibers as well as that a common source of alignment errors is eliminated. The non-segmented surface to which the optical fibers are connected. also eliminates the possibility of overlapping the oluno elements. which could otherwise be caused by deviations from acceptable manufacturing tolerances or possible assembly errors. Although the connector according to the invention is particularly well suited for optical cables with duplex fibers, the connector can be easily modified to fit optical cables, which have only one fiber channel, optical cables with several fiber channels and flat networks, ie. fiber optic cables having any number of channels, by giving the through hole or holes a shape similar to the cable in question in a manner readily apparent to those skilled in the art.

The above description of the invention has been made for illustrative purposes. It will be appreciated that those skilled in the art may propose modifications in the details set forth above without departing from the scope of the invention.

Claims (15)

7906775-7 10 15 20 25 30 35 40 B PATENT CLAIMS Connectors for connecting one or more optical fibers to a fiber optic component or to other optical fibers, comprising a plug means (24) having first and second, transversely mating plug portions for holding said optical fibers therebetween. e-characterized in that the first plug portion (26) comprises a front end with a continuous forward facing surface (52) extending in front of the second plug portion (28), said optical fibers (20) extending through the front end of the first plug portion up to the front surface (52), said plug means (24) being arranged to be inserted into a mating housing means (30) with the continuous, forward-facing surface of the plug means positioned to optically couple said optical fibers to the fiber optic component or components. other optical fibers. Connector according to claim 1, characterized by a locking device (40, 42) for holding said continuous, forward-facing surface (52) of the plug member (24) against said fiber optic component in a touching position. of that mentioned Connector according to claim 2, characterized in that the locking device (40, 42) releasably holds the plug means (24) in the housing means (30). Connector according to claim 3, the device comprising a locking hole (40) in one plug member (24) or the housing member (30) and a locking bead (42) in the housing member (30) or the other characterized in that the locking plug member (24 ) to cooperate with the barrier hole (40). Connector according to claim 4, characterized in that the distance between the barrier hole (40) and the fiber optic component is less than the distance between the barrier bead (42) and the fiber optic component, the difference between these distances being sufficient to push the continuous, forward facing the surface (52) towards the fiber optic component while the plug means (24) is releasably held in the housing means (30). Connector according to one of the preceding claims, characterized by a limiting device (36) for restricting the insertion of the plug means (24) into the housing means (30). Connector according to claim 6, characterized in that said limiting device comprises at least one shoulder (36) on the plug device (24) for cooperating with the housing means (30). Connector according to claim 1, characterized by a device (48, 50) for preventing axial displacement between the first (Z6) and second (28) plug portions. Connector according to claim 8, characterized in that said device (48, 50) comprises at least one groove (48) in one plug portion and at least one complementary strip (50). in the second plug portion, the strip (50) cooperating with the groove (48) to prevent axial displacement between the first (26) and second (28) plug portions. Connector according to claim 1, wherein each plug portion has transversely mating surfaces. characterized in that each of the transversely mating surfaces of the plug portions is provided with grooves (54, 56, 58, 60, 62) which together form an axial hole through the plug member (24) when the plug portions (26 , 28) are interconnected, the hole (54, 56, 58, 60, 62) extending through the first plug portion to the continuous, forward-facing surface (52), and the optical fiber being in said hole (54, 56, 58, 60, 62), when the plug portions (26, 28) are interconnected. Connector according to any one of the preceding claims, characterized in that each optical fiber (20) is arranged in a fiber-optic cable characteristic - (12), each fiber-optic cable (12) comprising an outer insulating sheath (16) and a reinforcing element. (22) arranged inside the outer sheath (16), the optical fiber (20) being arranged inside the reinforcing element (22) and further provided with an inner insulating sheath (18). Connector according to claim 11, characterized in that the through hole (54, 96, 58, 60, 62) in each plug member (24) comprises a small diameter portion (54) for receiving one of the optical fibers ( 20), a relatively larger diameter portion (56) for receiving the inner insulating sheath (18) on the optical fiber (20) and an even larger diameter portion (58) for receiving the outer insulating sheath (16). ) on the fiber optic cable (12), which contains the optical fiber. Connector according to claim 12, characterized in that the through hole (54, 56, 68, 60, 62) further comprises a conically shaped portion (62) for receiving the reinforcing element (22) of one of the fiber optic cables. (12). Connector according to any one of the preceding claims, in that the housing means (30) and the plug means (24) are provided with complex angular alignment means (44, 46) for effecting polarized coupling of the housing means and the plug means. Connector according to claim 14, characterized in that the housing means (30) or the plug means (24) is provided with an axial, inner groove (46) and the plug means (24) or the housing means (30) is provided with a projecting strip (44), which can be placed axially in said groove (46).