RU2179733C2 - Socket with electrooptical device - Google Patents

Abstract

FIELD: gears for interconnection of optical fibers. SUBSTANCE: socket has body with hole, flap, body attachment aid, separable plate, backing, limit fixing arm. The latter includes base and boss with groove for placement of fiber. Base has lens. EFFECT: fast connection and disconnection of optical fibers, simplified installation of optical fibers. 20 cl, 15 dwg

Description

BACKGROUND OF THE INVENTION
1. The technical field to which the invention relates.
The present invention mainly relates to devices for interconnecting optical fibers, and more particularly, to a device for terminating at least one optical fiber used as a telecommunication line (for transmitting speech, information data, video signals, etc.) with active optical device, for example, with a photodetector or solid-state light source.

2. Description of the Related Art
Optical fibers replaced the copper wire due to the characteristics that are more preferable for transmitting telecommunication signals. As in the case of copper wire, it is necessary to ensure the interconnection of optical fibers during installation, repair or replacement of these fibers and for the introduction of fibers into active optical devices. These optical devices include, in particular, optical sensors (photodiodes) and light sources (light emitting diodes, laser diodes). The termination of the optical fiber may be indirect, i.e. the fiber can be attached to some other (passive) optical device, for example, a beam splitter or polarizer, before the light beam is directed to the active optical device. The main objective of the present invention is to provide a socket for terminating optical fiber.

 The optical fiber connector described in US Pat. No. 5,381,498 has a plug and a receptacle. The plug has a receiving V-groove for accommodating each fiber to be interconnected, with the end of the fiber located in the middle of each groove. The socket has a plate that is retracted when the plug is inserted, as a result of which another fiber is lowered into the V-groove of the plug. After the plug is fully inserted, the ends of both fibers are in contact with each other, and the fiber fixed in the socket elastically deforms to provide a constant compressive load between the contact ends of the fibers. This connector provides quick disconnection and reconnection of multiple pairs of optical fibers without the use of ferrules or other centering elements. In order to withstand repeated bushings and bends, high strength fibers can be used. The accuracy of the length of the fibers (i.e. the relative location of their contact ends in the plug and socket) is not critical, since the tolerance is provided by the slack selected by the curved fiber of the socket (the end part of the fiber attached to the plug does not bend, but always remains straight) .

 The ends of the fibers can be prepared by simple dissection and chamfering; if desired, the end surfaces can be dissected at an angle (i.e., not perpendicular to the fiber axis) to reduce signal reflections.

 In many splices of optical fibers, plate elements are used having grooves for accommodating the fibers with means for fixing the contact ends of the fibers in the common groove. Some of these devices are designed to interconnect multiple pairs of fibers, such as the splice described in US Pat. No. 5,151,964. In the device of US Pat. No. 4,028,162, the fibers are brought into the centering groove at a certain angle of slip and are temporarily held during interlocking of the connector plate to the interconnected fibers. Other examples of methods utilizing the insertion of curved fibers into the centering grooves are described in US Pat. the number of parts, such as the designs described in US Pat. Nos. 4,045,121, 4,218,113, and 4,767,180. In the apparatus of US Pat. No. 4,322,127, a centering plate holds the fiber in the mold groove while injection molding is carried out around the fiber processes. The cured plug can then be removed from the mold.

 US 5381498 uses the principle of fiber bending, but this connector has several drawbacks. For example, the design of the plug allows dust to easily settle on the ends of the fibers, since these ends are exposed, being above the grooves to accommodate the fibers. The fibers in the outlet can likewise become dirty due to the absence of a leaf or other opening protection elements in the absence of a plug. Although the connector of US Pat. No. 5,381,498 has fewer parts than most connectors using ferrules, it would be preferable to exclude movable parts. for example, a sliding plate and a spring inside. For this design, the use of high-strength fibers in the outlet is also recommended, which makes it less compatible with the embedded base for standard fiber. This patent, as well as some of the patents mentioned above, does not explain how the device can be used for termination. In this regard, there was a need to develop an outlet with an active device, which would similarly provide quick disconnection and connection of one or more optical fibers, and would be easy to install and use, but would not have the above-mentioned limited capabilities without compromising performance or increase in value.

Summary of the invention
The present invention provides an optical fiber receptacle, generally comprising: (i) an end retainer having a protrusion with a fiber centering groove formed in the protrusion and a base attached to the protrusion and having a fiber stop, and (ii) means for centering the end latch relative to the active device. The socket is advantageously used in combination with a plug having a hollow body with an end distant from the center, the plug cavity having sufficient space to bend the end of the exposed optical fiber, and the end distant from the center has a slot providing access to the end of the fiber. The socket has a hole with dimensions that allow receiving the end of the plug housing that is remote from the center, and the end clamp is positioned so as to position the centering fiber groove in the receiving position of the end portion of the plug fiber when the plug body is inserted into the socket. When the plug housing is fully inserted into the socket, the fiber of the plug is bent to provide a constant compressive load relative to the stop for the fiber. Bending the fiber of the plug also provides a snug fit in the fiber-centering groove. For detachable fastening of the plug housing in the socket, fixing means are preferably used. The plug can be pushed back in the interconnected position to the locking means to minimize the effect of manufacturing tolerances.

 For functional communication with the light transmitting part of the end retainer, i.e. With the contact end of the fiber, various active devices, such as photodetectors or solid-state light sources, can be respectively located near the end clamp. The end lock can be mounted on a substrate, on which the active device is also located, and this substrate is located inside the outlet. Larger sockets with multiple holes can be created to accommodate a series of end clips for simultaneously terminating multiple fibers. Thus, the socket of the active device has many advantages of the connector, for example, such as ease of use and quick connection, disconnection and reconnection. The end clip may also be designed to receive one of many different optical plates having, for example, a lens, to simplify manufacturing and assembly.

Brief Description of the Drawings
The present invention will become more apparent when considering the accompanying drawings, on which:
FIG. 1 is a longitudinal section of a fiber optic connector including a plug used in the present invention.

 FIG. 2 is a perspective view of a plug and socket for interconnecting the fibers of FIG. 1, in partial section, showing curved fibers inside a plug.

 FIG. 3 is a perspective view of one embodiment of a plug used in the present invention with a sliding leaf.

 FIG. 4 is a perspective view of another embodiment of a plug used in the present invention with the plug housing removed to show internal parts.

 FIG. 5 is a perspective view of one embodiment of a receptacle for interconnecting fibers used in conjunction with the plugs shown in FIG. 1-4, with a hinge leaf having cam surfaces cooperating with cam surfaces on a plug flap.

 FIG. 6 is a perspective view of an end retainer that can be used in an outlet of an active device of the present invention.

 FIG. 7 is a longitudinal section of a termination in which the plug and end retainer shown in FIG. 6.

 FIG. 8 is a sectional view of a tool used to clean the ends of the fibers in a plug.

 FIG. 9 is a sectional view of a tool used to clean the ends of the fibers in a power outlet.

 FIG. 10 is a side view of one embodiment of an outlet of an active device of the present invention.

 FIG. 11 is a bottom perspective of the outlet of the active device shown in FIG. 10.

 FIG. 12 is a perspective view showing two end clamps of optical fibers and an optical plate used with one or more such clamps.

 FIG. 13 is a side view of one of the optical plates.

 FIG. 14 is a side view of an end retainer from a series of the same retainers mounted on a substrate for electrical interconnection.

 FIG. 15 is a view of a modified end retainer.

Description of a preferred embodiment of the invention
In the drawings, in particular in FIG. 1 and 2, an optical fiber connector 10 is provided having a plug 12, which is particularly suitable for use in conjunction with the present invention. See U.S. Patent Application Serial 08/577740. The connector 10 is designed for interconnecting fibers and additionally has, basically, a socket 14 for interconnecting fibers. In FIG. 1 is a longitudinal section of a connector 10 showing a plug 12 fully inserted into a socket 14 and a socket 14 mounted on a support surface or partition 16. FIG. 2 is a perspective view without a partition 16, also with a partial section, for showing the inside of the connector. The presented embodiment is intended for the interconnection of two pairs of fibers, but those skilled in the art should understand that the embodiments of the invention described in this text apply to both the interconnection of one pair of fibers and the interconnection of several pairs of fibers.

 Plug 12 also shown in FIG. 3, comprises a fiber holder 18, which may consist of two clamping elements or pads 20 and 22, and a plug housing 24 attached to the fiber holder 18. The housing 24 can be detachably attached to the fiber holder 18 by, for example, latches 26 that are molded integrally with the pads 20 and 22 and engage with cutouts 28 made in the respective walls of the housing 24. The fibers 30 and 32, which must be mutually connected or attached, pass through the holder 18 into the hollow interior of the housing 24. The end parts of the fibers are exposed, i.e. they are not attached to any centering part, for example, to the tip. Therefore, the housing 24 not only facilitates the physical placement of the plug 12 in the socket 14 for interconnecting the fibers, but also protects the otherwise open end portions of the fibers (if necessary, the housing can be retracted to fully open the ends of the fibers). The holder 18 has grooves 34 for accommodating fibers made in the adjacent surfaces of the pads 20 and 22. The last two parts can be made identical. The holder 18 can fix the fibers, for example, by means of a retainer, by means of adhesives, or both. Alternative means can be used to attach the fibers to the holder 18. The holder 18 may have a protruding portion 36 covering the fibers for additional stress relief and clamping. For greater stress relief and capture of the reinforcing elements of the optical cable (Kevlar cores), as well as to facilitate handling of the plug 12, a protective cap 38 may be provided. The reinforcing elements should not be crimped, but they can be fixed to the holder. The stress relief of the reinforcing elements is achieved by tightening the straight section of the optical fiber holder of the plug in the protective cap. It depends on the choice of materials for the protective cap and the fiber holder of the plug, which allows you to create a design that does not require a crimp ring and which simplifies the manufacture and reduces the number of required components. In another case, the protruding part can be made on the holder with a "distorted" (irregular shape) channel for fixing the reinforcing cores and fixing the protective cap by means of a tight fit. Unidirectional teeth on the surface of the plug fiber holder help secure the protective cap to the holder, which also helps to fasten the cable to the plug.

 In the embodiment shown in FIG. 1 and 2, on one side of the housing 24, a latch 40 is molded in one piece for releasably securing the plug 12 in the socket 14. This latch also provides mechanical polarization of the plug, i.e. the plug can be inserted into socket 14, orienting it in only one position. The plug 12 can be displaced in the position of connecting the fibers to each other, for example, using a leaf spring (elastic cantilever) made inside the socket 14, which abuts the latch 40, to reduce the influence of manufacturing tolerances.

 In FIG. 4 shows a slightly different example of the implementation of the plug 12 ', suitable for use with a socket with an active device of the present invention. In this embodiment, a similar housing is used, which is not shown in FIG. 4 for a better illustration of an alternative fiber holder 18 'and internal parts. The holder 18 'here also has two pads 20' and 22 ', but in this embodiment, these two pads are not identical. Firstly, the block 22 'has a protruding part or platform 42 with several vertical pins 44, 46 and 48. These pins are designed to guide the fibers inside the housing 24 to the desired position for placement in the V-grooves of the socket 14, as will be discussed below, and to limit the skew of the fibers in order to ensure the required alignment of the ends of the fibers in the holes in the housing 24. The latch 40 'is molded integrally with the block 22' and is located along the lower side of the platform 42. Secondly, the channels for the fibers in the holder 18 'are made in view e V-grooves 34 'only in the block 22', and the corresponding surface of the block 20 'is made flat to create only three surfaces for the fiber retainer. In addition, the V-grooves 34 'in the block 22' have additional recesses, and protrusions 50 are formed on the block 20 ', which enter these recesses and facilitate the required fastening of the blocks to each other.

 When the plug 12 (or 12 ') is not inserted into the socket 14, the fibers 30 and 32 are located almost rectilinearly in the housing 24. The “practically” rectilinear arrangement of the fibers means that they are located without significant bending, although they may have a slight deflection due to their own weight or plastic deformation.

 However, there is sufficient free space inside the housing 24 for significant fiber bending, as can be seen in FIG. 1 and 2 when the plug is fully inserted into the outlet. The front end 52 of the housing 24 has two slots 54 and 56 formed in it, which provide access to the contact ends of the fibers located in the housing 24. At the front end 52 of the housing 24, a hood or sash 58 with two covers or strips 60, 62 is slidably attached which overlap respectively the slots 54 and 56 when the sash 58 is in the closed position, as shown in FIG. 3. When the sash 58 is slid open, the slats 60 and 62 move and, accordingly, provide access to the fibers 30 and 32 through the slots 54 and 56, which eliminates the need for the fibers to extend beyond the housing 24, although this may be acceptable in alternative designs. The shutter 58 is mounted on the housing 24 with the possibility of sliding with a snap created by two latches 64 and 66 of the tongue-and-groove type (Fig. 1). In addition to preventing dust from entering through the slots, the sash 58 also prevents light from coming out of the optical fibers of the plug, which could injure the user's eyes. As will be discussed below with reference to FIG. 8, the sash 58 may also open one or more openings in the upper part of the housing 24 in its open position, into which pushers can be inserted to push the fibers out of the openings 54 and 56 to ensure that the ends of the fibers are cleaned.

Other sash designs may be offered for the plug. For example, the plug may have a flap (not shown) that rises vertically during insertion of the plug. This is done by planting the sash in another part, for example, in a slide gate that moves inside the case. The slide gate has a vertical slot on each of the side walls and is open at both ends. The continuous leaf has a pin that extends through the side walls of the shutter and enters slots in the housing, which are in the form described below. Each slot begins with a section directed upward at an angle of about 30 ^° and having a length of about 1 mm, then becomes horizontal over most of its length, after which it again rises by about 1 mm and ends with a second horizontal section (about 1.5 mm long) . When the plug comes in contact with the stop in the outlet, it pushes the shutter back inside the housing. During the first few millimeters of travel, the sash rises to its original position. In this position, the fibers come in contact with the leaflet, which deflects the fibers downward at an obtuse angle, although this is not necessary. The leaf may also act as a centering mechanism. This helps to prevent the end faces of the fibers of the plug from contacting the V-grooves when the fibers come into contact with the V-grooves.

 Before the plug is fully inserted, the shutter reaches the second angle-directed slot in the housing. At this point, the sash rises to its final position, in which it no longer comes in contact with the fibers, as a result of which the fibers can freely bend and create sufficient pressure on the outlet. The return of the shutter and sash is carried out by a spring, which creates a pushing force between the fiber holder and the shutter. A special advantage of this design is that it opens the entire end of the plug without any slot, as a result of which the fibers can freely pass before contact with the V-grooves.

 In another design (not shown), the shutter slides across the plug again when the plug is inserted using the shuttle, which moves inside the housing. The shutter has vertical slots in each of its side walls and an open end closest to the fiber holder. The shutter portion closest to the front of the housing has a closed end with two vertical slots that are in line with the fibers and extend from top to bottom. This casement is simply a rectangular plate with two vertical slots that start at the bottom and end, not reaching the top, about the distance of two thicknesses of material. In addition, the plate has a cutout in its upper part, which moves along the crest of the housing. This comb acts as a cam mechanism for the sash. The cam is located on the inside of the top of the housing. At the front, it starts at an obtuse angle until it reaches the center, where it goes down along its entire length. In the closed position, two rows of slots in the shutter and sash are offset relative to each other, providing a closed state of the plug. When the plug comes in contact with the stop at the outlet, it pushes the shutter back inside the housing. During the first few millimeters of the stroke, the sash slides sideways in the housing while moving the shutter back. When both rows of slots are in the same line, forming an open slot for the passage of fibers, the sash reaches a straight section of the cam. At this moment, the lateral movement of the sash stops, and the sash is pushed back by the shutter in the housing. The return of the shutter and sash is carried out by a spring, which creates a pushing force between the fiber holder and the shutter. With this design, the entire end of the plug is also opened and smooth operation of the sash is ensured. Changes in the design of the plug of the present invention will become apparent to those skilled in the art after reviewing the previous description.

 To test the outlet in operation, you can use the test plug. This plug can be substantially identical to the plug described above, except that it accommodates one fiber coiled so that both ends of the fiber extend to a power outlet. Thus, the signal can be applied along one of the fibers of the socket, received by the loop fiber in the plug and sent to another fiber of the socket, which will transmit the signal to the test detection system.

 Rosette 14, also shown in FIG. 5 includes a body or body 70 and another fiber holder 72. The housing 70 has an opening 74, the dimensions and shape of which practically correspond to the dimensions and shape of the front end 52 of the plug 12. The housing 70 may also have corresponding parts (for example, levers 76 of latches), which make it possible to detachably attach the socket to the partition 16, which can be, for example, a patch panel or the output part of a workstation (front panel of a wall box). The latches allow mounting on the front of the panel so that all the preparatory work is done on this front side, or mounting on the back of the panel so that all the preparatory work is done on the back of the panel. Socket fibers (only one of which, 78, is shown in FIGS. 1 and 2) are fixed in the socket fiber holder 72 by means of their latch using a locking plate 80 adapted to grasp the fibers at the first end of the holder 72. The contact ends of the socket fibers extend into the centering fiber grooves made in protrusions or fingers 82 and 84 at the second end of the fiber holder 72 of the socket. These grooves are preferably V-shaped, although they may be more rounded, i.e. U-shaped. The intermediate portion 86 of the fiber-centering grooves is curved in order to hold the fibers of the outlet in the grooves by resiliently pressing slightly curved fibers. Additional means may be provided, for example, a fiber clip shown in FIG. 9, for securely attaching fibers in the grooves. The fibers do not reach the very ends of the fingers 82 and 84, but end at a considerable distance from these ends to provide the required support for the fibers of the plug when using the connector. If the fibers mutually contact each other very close to the ends of the V-grooves (or if the plug is inserted too deep), the fiber of the plug may bend outside the groove and rise above the top of the groove, disrupting the connection.

The number of fingers with the fiber-centering grooves in the socket 14 should correspond to the number of fibers in the plug 12. The fingers 82 and 84 are shaped so that they respectively enter the slots 54 and 56 of the housing 24 when the plug 12 is fully inserted into the socket 14. The fingers 82 and 84 enter the housing 24 at an angle to the axis of the plug, i.e. the axis defined by one of the fibers 30 or 32 of the plug when they are located rectilinearly inside the housing 24. This angle is preferably approximately 42 ^o , which compensates for problems related to the contact pressure of the end surfaces of the fibers, the forces of the fibers directed towards the V-shaped grooves, the effect of friction and the desired tolerance field (tolerances increase with increasing angle). Since the fibers of the outlet are not directed toward the hole 74, there is no risk of light coming out that could damage the user's eyes. The socket fiber holder 72 is pivotally attached to the housing 70 by means of pins on the first end of the holder, which snap into the cutouts or hooks 88 made at one end of the socket body 70. The holder 72 is detachably locked in place by posts or tabs formed on the side of the holder that engage with holes 89 in the housing 70 of the outlet. An alternative design of the outlet fiber holder can be used, in which the holder is molded in one piece with a detachable top or cover that can snap into place on its base having grooves for positioning the fibers.

 The receptacle 14 for interconnecting the fibers (like the termination receptacle described below) may also have a shutter or a shutter 90 to minimize the entry of contaminants through the opening 74. In the described embodiment, a shutter is used that interacts with the shutter of the plug so that set the flap 58 of the plug in an intermediate position between the closed and open states when the plug 12 is inserted into the socket 14. More specifically, the flap 90 of the socket has two cam surfaces 92 and 94, which are respectively, interact with cam surfaces 96 and 98 on the flap 58 of the plug. The shutter 90 of the socket rotates relative to one of its edges due to the presence of pins 100, which snap into the cutouts 102 of the housing 70 of the socket. Means (not shown) such as springs or cam links formed integrally with the sash can be used to bias the sash 90 in the closed position. When the plug 12 is inserted into the socket 14, the front end 52 and the sash 58 of the plug abut against the sash 90 of the socket, lifting and opening the sash. Then, the inclined cam surface 94 begins to press against the cam surface 98 of the flapper 58 of the plug and pushes the flap 58 to the side, opening the slots 54 and 56. If after that the plug 12 is removed from the socket 14, then the inclined cam surface 92 likewise presses the cam surface during undocking the plug and pivots the sash 58 back to its closed position. The housing 24 has grooves or recesses 104 and 106 to accommodate the cam surfaces 92 and 94 when the plug is in the socket, which also contributes to the additional reliability of the connection. With the socket 14, sashes of other designs can be used, for example, a sash that opens outward manually and clicks in the closed position.

 The socket may also have a sash that acts as a latch to secure the plug. In this alternative construction (not shown), the plug body (housing) has a cutout portion on the underside. The leaf of the outlet is a rectangular spring plate with a tongue (cantilever beam) protruding relative to its lower part when the leaf is in the closed position. When the plug is inserted into the socket, the leaf turns from vertical to horizontal. After the plug is fully inserted, the cut-out releases the upper edge of the leaf. Then the sash elastically returns upwards by several degrees and reaches the cutout area. This provides a fixation of two parts. Unlocking the plug is done by squeezing the plug and the reed of the sash. In this case, the sash returns to its horizontal position and allows you to remove the plug from the outlet. The tongue can be shaped so that when undocking the plug, sufficient friction is not created to hold the finger on the tongue. This solution simplifies the design of the plug.

 In addition, the outlet can be further modified by using internal latches for mounting in two different positions on the wall or partition. In this case, in the first position, the latch is fully functional and is flush with the wall, and in the second position, it protrudes slightly outward relative to the wall. This provides access to the inside of the outlet for cleaning.

 The mechanism for interlocking the plug and socket can be successfully designed to prevent breakage of the plug assembly when the cable of the plug cable is exerted too much tension, for example, when someone hooks on the cable. This is achieved by creating such a latch geometry that allows you to undock the plug from the outlet when the cable tension exceeds a predetermined undocking force. As a result, the plug is undocked from the outlet, and not the cable is pulled out of the plug. This feature is even more acceptable because the shutter of the plug automatically closes after removing the plug from the outlet.

 All components of connector 10 (except the protective cap 38) can be made of any wear-resistant materials, preferably injection molded polymers, such as polycarbonate, VALOX polyester (sold by General Electric), or RADEL polyaryl sulfon (sold by Amoco ) The material may contain electrically conductive fillers to impart semiconductor properties to the components to minimize the formation of triboelectric charges, which can cause contamination of the fiber ends.

 The protective cap 38 is preferably made of a low modulus copolyester elastomer, for example, material manufactured by RTP (Winona, Minnesota) under the number 1559X67420B.

 Assembling and mounting connector 10 are simple operations. The plug 12 is usually assembled at the factory, although it can be easily assembled on site. In this regard, the term "pre-terminated" in this context refers to the installation of optical fibers in the plug 12 or socket 14, regardless of whether this installation takes place at the factory, on site or elsewhere. It is also obvious that the plug 12 or socket 14 can be mounted on a jumper cable or patch cord that have any type of connector on the other end of the fibers. It is recommended that the fibers used have a longer service life when exposed to indoor environmental conditions, such as high-strength fibers manufactured by the Minnesota Mining and Manufecuring Company (i.e., 3M, the patent holder of the present invention). These fibers have a conventional core and sheath, enclosed in a new three-layer structure, as described in US Pat. No. 5,381,504. It will be apparent to those skilled in the art that this connector may comprise individual optical fibers or multi-fiber tapes, as well as single-mode and multi-mode fibers.

 Fibers that must be pre-plugged into plug 12 or socket 14 must be stripped, cut, and cleaned. If the fibers are a tape that is part of a bundle of tapes in a cable, you must first remove part of the cable jacket to expose the tape. Most cables have several protective layers, and each of these layers must be removed to allow access to fiber tapes. Similar operations must be performed to remove the protective layers of the cable having a single fiber. After the fibers have been freed from the cable jacket, they must be stripped. After that, the stripped fibers are ready for dissection, which can be performed by any of the commercially available fiber spreaders, for example, as described in US Pat. No. 5,024,363. The cut-off length for attaching the fibers in the plug 12 is a distance from the fiber holder 18, which is approximately 23 mm. For attaching the fibers to the socket 14, the cut-off length is the distance from the fiber holder 72, which is preferably about 15 mm. The fibers should be cleaned of all waste using a lint-free cloth. Before removing fibers from the divider, the master should inspect the fibers to make sure the end surfaces of all the fibers are acceptable, i.e. in that they are dissected evenly and have no sharp protrusions. For inspection, the viewing device described in US Pat. No. 5,210,647 may be used. Once the person is satisfied that each of the fibers has an acceptable end surface, the fibers can be removed from the divider. In a preferred embodiment, the ends of the fibers are flat surfaces that are chamfered (or at least partially chamfered) from their peripheral edges to provide benefits from such a fiber end profile as described in more detail in US Serial 08 / 122755. In another case, the end surfaces of the fibers may have a rounded shape (mainly spherical). In addition, the fibers can optionally be subjected to asymmetric processing, for example, dissection with the creation of inclined end surfaces, as described in US patent 5048908. In this case, to minimize insertion loss and reflections, the fibers must be inserted so that the orientation of the inclined end surfaces of one set of fibers (i.e., in plug 12) complemented the orientation of the inclined end surfaces of another set of fibers (i.e., in socket 14). The preparation of the plug fibers can be performed after the optical cable is passed through the protective cap 38.

 The final assembly of the plug 12 includes simple fiber retainer operations in the V-grooves of the holder 18 and snapping the housing 24 onto the holder 18. You can use the assembly tool to guide the housing 24 relative to the fiber of the plug to prevent damage to the fibers when they are inserted into the housing. The ends of the plug fibers should be approximately 0.5 mm from the end of the housing. The final assembly of the socket 14 is also simple. The outlet fibers are clamped onto the fiber holder 72 by means of a pressure plate 80, the ends of the outlet fibers being located in the fiber centering grooves at a distance of about 15 mm from the ends of the fingers 82 and 84. The outlet fibers can be cut after attaching them to the fiber holder. Fibers can be assembled in the holder using a V-groove to actually remove the fiber holder from the divider to prevent contamination of the ends of the fibers if mating and guiding parts are provided on one or both of the parts. You can also use a stamp type tool to simplify assembly. The fiber holder 72 is attached to the housing 70 by first introducing the rotation axes into the cutouts 88 and then snapping the protrusions into the holes 89. Care must be taken when inserting the fibers into the V-grooves and attaching the holder to the slot so as not to contaminate the ends of the fibers.

 Mounting the connector 10 is also simple. The socket 14 is mounted on any desired surface using conventional means, for example, latch levers 76 (for conventional installation, the housing 70 can be molded with other structures for mounting). You can also assemble several outlets into one module, and they can be designed for front or rear installation, or for input from the side. After mounting the socket 14, the connection is made by simply inserting the plug 12 into the hole 74. The plug 12 is released from the socket 14 using the latch 40.

 In FIG. 1 and 2, the plug is shown in the fully inserted position. During insertion of the plug 12, the flap 90 opens and opens the flap 58 as described above, allowing the fingers 82 and 84 to enter the slots 54 and 56, respectively. The fibers 30 and 32 of the plug come into contact with the fiber-centering grooves in the fiber holder 72 and slide along grooves until their end surfaces are joined end-to-end with the corresponding end surfaces of the fibers of the socket, after which they begin to bend when the plug is fully inserted into the socket. The fiber of the plug can be bent S-shaped. All the effort at the fiber interface is due to the elasticity (elastic deformation) of the curved fibers 30 and 32, which provides a constant compressive load between the ends of the fibers. Connector 10 is preferably designed to maintain a minimum bending radius of 7.6 mm.

The dimensions of the various components of the connector 10 can vary significantly depending on the desired application. The following approximate dimensions should be considered as approximate. The plug 12 has a total length of 57 mm, a width of 12 mm, and a thickness of 8 mm, and the plug fiber holder 18 has clamping grooves of 13 mm length. The housing 24 of the plug protrudes beyond the edge of the holder 18 by 25 mm, forming an internal space 24 mm long, 10 mm wide and 6 mm high. The hole 74 of the socket 14 has a size of 12 • 10 mm. The total height and depth of the outlet are 38 mm and 36 mm, respectively. The socket fiber holder 72 has a length of 20 mm (counting from the end where the fibers are pressed against the ends of the fingers 82 and 84), a width of 12 mm, and a thickness of 1.5 mm. The centering fibers of the grooves in fingers 82 and 84 have a length of 11.5 mm and a maximum depth of 2 mm, which allows the placement of most conventional optical fibers. The inner corner of the V-grooves should not be too small, as this can create excessive friction of the fibers, but it should not be too large, as this will not provide the required direction of the fibers. A good compromise is an internal angle of 90 ^o .

 An object of the present invention is to terminate optical fibers, which is particularly useful with the connectors described above for interconnecting fiber with fiber.

 In FIG. 6 illustrates one embodiment of an end clip 110 of the present invention adapted for use with an active device. The end clip 110 practically replaces the fiber holder 72 of the socket 14 for interconnecting the fibers and has a base 112 and a protrusion or finger 114, similar to the fingers 82, 84. The finger 114 has a fiber centering groove 116 to accommodate one of the fibers of the plug, the end surface of the contact end of which is suitable to the fiber stop or surface 118 as shown in FIG. 7. The force acting on the fiber is designed to be sufficient to exclude any air gap between the end surface of the fiber and the stop 118, but it is not so large as to worsen the end surface of the fiber when the latter moves across the stop 118, for example from scratching. The light-transmitting material of the stop 118 is usually transparent (ie, transparent to the wavelength of light transmitted by the optical fibers), as a result of which the light signal passes through the material, which allows the active optical device to be placed on the other side of the base 112. The specified material may be coated, or may be otherwise made to influence the light signal, for example, to regulate the signal intensity or to polarize the signal. The pins 120, made on the basis of 112, can be used to align and fasten the end retainer 110 to the substrate of the active device, for example, a printed circuit board. A fiber column can also be placed in the V-groove, one end of which abuts against the fiber stop 118, and the other end is located in the intermediate part of the groove 116 for interconnecting with the fiber connected to the optical device.

 The end clip 110 preferably has a single structure made of injection molded polymer, such as ULTEM polyetherimide (manufactured by General Electric), and may further comprise a lens 122 formed opposite surface 118 to focus light from or to fiber. Active optical devices and their supporting structures are not included in the scope of the present invention, but may include, for example, photoelectric sensors or laser diodes. Other passive optical devices (beam splitting elements, fiber columns at the tips, etc.) that direct light to or from active optical devices can be used, and end clamps of various geometries can be used to direct the light or focus it in a specific location, including geometry options that use full internal reflection (TIR). The total internal reflection method for transmitting light from a bare fiber to a photodetector or from a light source into a fiber using the present invention provides several advantages. One of them is that the position of the fiber is determined by the stop for the fiber, which allows you to repeatedly place the fiber of the plug in the same position. Since the position of the end of the fiber is predetermined by the tolerances for manufacturing the molded part and the accuracy of the arrangement of active devices, i.e., a photodetector or light source, this eliminates the need for alignment of the active optical device. Another advantage is that by S-bending the fiber, the overall height of the transceiver module can be reduced. S-shaped bending can also be used in the connector for two parallel, but not coaxial fibers. And finally, the electronic circuits of the transceiver can be mounted on a board located in the same plane in which the connector is inserted. In the end connection of the active device can also be used a fiber column (not shown), mounted in a holder similar to the holder 72 of the socket.

In addition to providing quick and easy connection and disconnection, connector 10 has several other advantages. As mentioned above, it can be easily pre-assembled both in the field and in the factory. Even in the case where the fibers in the plug or socket do not end exactly at the desired location, full mutual contact of the fibers in the assembled joint is still ensured, since the elastic deformation of the curved fibers creates a positive stop force. In other words, tolerances on the relative arrangement of fiber pairs are expanded due to the presence of slack in the fibers of the plug. The plug 12 is substantially protected from being pulled out due to this. Tolerances are also not critical in the transverse arrangement of a given pair of fibers, since the V-shaped grooves 36 serve to center the fibers and the fibers are pushed towards the top of the grooves. The surface texture of the centering fiber grooves must be smooth and the angle of the grooves must be accurate; this texture can be easily obtained using standard injection molding technology. The top of the V-groove should preferably be pointed with a radius of not more than 0.025 mm. For the base of the V-shaped groove, it is recommended to use a solid material that is resistant to abrasion, but at the same time having a low coefficient of friction to minimize the friction forces acting on the fiber during its sliding in the groove. In addition, since the fibers of the outlet enter the housing 70 at an oblique angle (up to 90 ^° ) relative to the axis of the plug, this requires a very small depth for installation. Moreover, the mounting methods are compatible with the mounting methods of RJ45 sockets. And finally, the reduced number of parts and the fact that all parts can be manufactured by injection molding, contribute to a fairly inexpensive connector.

 In FIG. 8 and 9 show tools that can be used in conjunction with the present invention to clean the ends of various optical fibers. In FIG. 8 shows a tool 130 used to clean the ends of the fibers in the plug 12. The tool 130 has a hand-held housing 132 with an opening 134 in the housing 132 for receiving the plug 12. The tool 130 also has a drive element or lever 136 pivotally connected to the housing 132 in position 138. In FIG. 8, the lever is shown in the operating position in which the pushing rod or plate 140 enters the hole or slot 142 in the upper part of the plug housing and contacts the fibers of the plug, pushing them out of the housing through the slots 54, 56. In the idle position, the lever 136 moves away from the hole 132 and retracts the push plate 140, so that the plug 12 can enter the tool 130 without colliding with the push plate. The lever 136 is preferably pushed towards the idle position, for example, using a spring.

 The hole 134 and the lever 136 are arranged so that the plug fibers push against the adhesive surface 144 of the strip of tape 146 when pushing through the slots of the body. The tape 146 peels off the tape reel 148, which is located inside the tool body 132. Two rollers 150 and 152 are provided that feed the tape so that the ends of the fibers always abut against a new portion of the adhesive surface. To facilitate use, the tape 146 can be wound on another roller 154, made in the form of a ratchet wheel engaged with the dog 156. This dog 156 is located on the other handle or pivot arm 158 connected to the device body at the point 160. With this design, the user can feed the tape and clean the plug fibers with the handle 158 while holding the tool. The handle 158 may also be pushed, for example, by means of a spring, to the extreme retracted position.

 In FIG. 9 shows a tool 162 used to clean the ends of fibers in a modified socket 14 '. The shape of the tool 162 resembles the shape of the plug 12, so that the device can be inserted into the socket 14 'similarly to the plug. The socket 14 'is basically identical to the socket 14, with the exception of some parts designed to raise the fibers of the socket from the V-grooves up and out to clean the ends of the fibers. These details include a fiber clip or retainer 164 and a deflector linkage 166. The fiber retainer 164 is pivotally coupled to the fiber retainer at position 168 and includes a pad or pad 170 at one end of the retainer lever 172 adapted to guide the fibers into the V-grooves and maintain proper fiber placement in these grooves. The pad 170 can be molded in one piece with a clip of fibers. A button or protrusion 174 is formed at the other end of the holder lever 172, which presses on the fibers of the outlet when the lock lever 172 is in the operating position, as shown in FIG. 9.

 Pressing the protrusion 174 on the fibers causes them to bend with the exit of the V-shaped grooves. The fiber retainer 164 is preferably pushed, for example, by a spring 176 towards the idle position, in which the push pad 170 is pressed against the fibers to hold them in the V-grooves.

 The tool 162 has a housing 178, in which, as with the tool 130, a feed coil 180 with adhesive tape 182 is also installed. The rollers 184 and 186 are designed to position the tape 182 so that its adhesive side can be fed back to clean the ends of the fibers . The fibers bend when the tool 162 enters the socket 14 'using a lever deflecting mechanism 166, which contains two deflecting levers 188 and 190 connected to each other at another pivot point 192. A protrusion or pushing column 194 made at the front end of the tool 162, pushes the deflection lever 188 when the tool is inserted into the outlet. This, in turn, causes the lever 190 to rotate, which abuts against the stopper or pin 196 attached to the fiber retainer 164. Forced contact between the deflecting lever 190 and the finger 196 causes the fiber retainer 164 to rotate about the axis 168, as a result of which the protrusion 174 presses the fibers and deflects them outward from the V-grooves. The tape 182 of the tool 162 may be wound onto another spool 198, or may exit the tool body 178 similar to that shown in FIG. 8 for the tool 130. A small dial or a pivoting handle protruding outward from the housing 178 may be attached to the take-up reel 198 to allow the user to feed the tape.

In FIG. 10 and 11 show additional elements of one embodiment of an outlet 200 of the active device of the present invention. In this example, the active device receptacle 200 includes a housing 202 that includes an end retainer 110 and is adapted to receive an optical fiber plug, such as plug 12. The housing 202 has a spring-loaded shutter 204 to prevent contaminants from entering the receptacle opening when there is no plug. The leaf 204 has corresponding snap elements 206 to complement the plug latch, for example the latch 40 'described above. The end latch 110 is mounted using its pins 120 on a substrate, for example, on the printed circuit board 208. The printed circuit board 208 also has an optoelectronic device 210 (for example, a photodetector or a semiconductor light source), which is located on the printed circuit board 208 in a corresponding position relative to the end lock , i.e. relative to the lens 122, and thus functionally connected to the contact end of any fiber, which ends in the retainer and abuts against the surface 118 (stop for the fiber). Any conventional active device may be used. Other components, such as LED drivers or data quantizers, may be mounted on the printed circuit board 208. The printed circuit board 208 is preferably mounted at an angle of about 48 ^° with respect to the axis of the socket housing, i.e. relative to the axis of the plug when it is inserted into the outlet, to position the protrusion 114 of the end clip at an appropriate angle to receive the contact end of the fiber.

 As seen in FIG. 11, means may be provided for attaching the outlet 200 to another structure, for example, to another printed circuit board (motherboard). This tool in this example contains several snap pins 212 attached to the lower side of the housing 202. The pins 212 can be molded integrally with the bottom plate 214, which is detachably attached to the housing 202 by means of additional latch levers 216 that are formed on the bottom plate and engage with holes or slots 218 made in the side walls of the housing 202. The latch levers 216 also serve to secure the substrate 208, as seen in FIG. 10.

 In FIG. 12 shows how several end clips can be arranged in a row, side by side, to receive a plurality of end terminations of optical fibers within a small volume. In FIG. 12 also shows the use of an insert or optical plate 220, which can be attached to any of the end clips to change the desired optical characteristics. For example, the plate 220 may have a lens 222 formed therein to complement or replace the lens 122. In the illustrated embodiment, the lens is formed using a diamond-shaped rod in a mold and has a radius of curvature of about 0.37 mm. The height of the lens is 0.10 mm and the remaining thickness of the optical plate 220 is approximately 0.56 mm. This lens 222 is used in conjunction with a lens 122 having a radius of curvature of about 0.30 mm and a height of about 0.25 mm. When the optical plate 220 is correctly positioned at the base 112 of the end retainer 110, the lens 122 is approximately 0.51 mm above the top surface of the plate 220. The distance from the fiber stop 118 to the bottom of the end retainer (ie, to the top of the substrate of the printed circuit board 208) is approximately 3.05 mm. The thickness of the light transmitting part of the base of the end retainer from the end of the lens 122 to the stop 118 for the fiber is approximately 1.02 mm If desired, other optical devices can be used, for example, polarizers, diffraction or hologram gratings, filters, microstructured surfaces, Fresnel lenses, etc. Such a device is located in a suitable place on the plate 220 for centering relative to the stop 118 for the fiber, and the plate 220 may have additional guide elements, i.e. have a guide key so that it can be located in the base 112 of the end latch 110 in only one orientation. A guide key can be obtained by performing on the plate 220 a bulge 224 included in a groove formed on the lower side of the base 112.

 In FIG. 14 shows how one of a series of end clips can be located on a substrate, for example, on another printed circuit board 226, with a side-by-side arrangement, as shown in FIG. 12. On the opposite side of the printed circuit board 226 can be made conclusions 228 for interconnecting the corresponding active optical devices with other control electronic circuits.

 In FIG. 15 presents two additional modifications of the end clip. The modified end clip 230 has two fingers or protrusions 232 and 234, each of which has a fiber receiving groove, positioned so as to create a double or S-shaped bend of the attached fiber 236. The end clip 230 also has a base portion 238, designed for complete internal reflection of the light signal. End clamp 230 can be made of two parts, one of which has protrusions with V-grooves and molded in one whole lens, and the other is a base with full internal reflection, also with one or more molded in one piece lenses. The various surfaces of the base may be coated to provide improved reflection, or may be in the form of lenses or other structured surfaces for internal focusing of light in any way desired. Lens recommendations for transmitting and receiving elements may vary. In some applications, the coating can be used to control the amount of reflected light.

 Although the present invention has been described with reference to specific examples of its implementation, this description should not be construed as limiting. After reading this description of the invention, it will become apparent to those skilled in the art that various modifications of the described examples are possible, as well as alternative embodiments of the invention. Therefore, it is contemplated that such modifications may be made without departing from the spirit and scope of the present invention as defined in the appended claims.

Claims (20)

 1. The latch for the end connection of the optical fiber containing a base having a light transmitting part; a protrusion attached to the specified base next to its light transmitting part, and the specified protrusion has a groove for accommodating the fiber, directed to the stop for the fiber located on the specified light transmitting part of the specified base; and means for centering said light transmitting portion of said base relative to the active device.  2. The end latch according to claim 1, characterized in that said base has a lens made in one piece with its specified light transmitting part.  3. The end lock according to claim 1, characterized in that said centering means comprises pins attached to said base.  4. The end retainer according to claim 1, characterized in that said light transmitting part of said base has a plurality of surfaces arranged so as to provide complete internal reflection of the light beam directed to said surface of the fiber stop.  5. The end latch according to claim 1, characterized in that it further comprises a contribution means for changing its optical characteristics.  6. The end retainer according to claim 1, characterized in that said groove for accommodating the fiber is almost straight and the stop for the fiber is almost perpendicular to said groove for accommodating the fiber.  7. The end retainer according to claim 2, characterized in that said lens is made on said light-transmitting part of the base opposite to the stop for the fiber.  8. The end retainer according to claim 5, characterized in that said insertion means comprises an optical plate, the dimensions of which provide for its landing in the corresponding cutout of said base next to its light transmitting part.  9. The end retainer according to claim 8, characterized in that said optical plate has a lens made in one piece with it.  10. The end lock according to claim 8, characterized in that said optical plate has mechanical polarization for landing in said cutout of said base in only one orientation.  11. A device for terminating an optical fiber, comprising a socket having a housing with an opening for receiving a contact end of the optical fiber; at least one end lock located in the specified housing, and the specified lock includes a base and a protrusion attached to the specified base next to its light transmitting part, and the specified protrusion has a groove for accommodating fiber, the first end directed mainly to the specified hole in the housing and the second the end directed to the stop for the fiber located on the specified light transmitting part of the specified base.  12. The device according to p. 11, characterized in that it contains at least one active device installed in the specified housing and located relative to the end latch so as to provide a functional connection with the specified light-transmitting part of the specified base.  13. The device according to p. 12, characterized in that the active device is mounted on a substrate, the specified end latch is mounted on the specified substrate, and the specified substrate is attached to the inner part of the specified case.  14. The device according to p. 11 or 12, characterized in that the said case has a leaf located near the specified hole and shifted to the closed position, and this leaf has a locking means for removable installation of the optical fiber plug.  15. The device according to p. 11 or 12, characterized in that the said housing has at least two of these end clamps and at least two of these active devices, which are respectively functionally associated with both end clamps.  16. The device according to p. 11 or 12, characterized in that it further comprises a contribution means for changing the optical characteristics of the specified end clamp.  17. The device according to p. 13, characterized in that said case includes a removable plate providing access to the inside of the case, said plate having latch levers that are attached to said case and securing said substrate in said case.  18. The device according to p. 15, characterized in that the two active devices are mounted on a common substrate, these two end clips are mounted on the specified common substrate, and the specified substrate is attached to the inside of the specified case.  19. An outlet with an active device, comprising a housing having an opening for accommodating an end portion of an optical fiber, a sash located near said opening displaced to a closed position and having fixing means for detachable input of an optical fiber plug, means for attaching said housing to an external structure and removable a plate providing access to the inside of said enclosure; a substrate attached to the inside of said body; at least one end retainer mounted on said substrate, wherein said retainer includes a base and a protrusion attached to said base near its light transmitting part, said protrusion has a groove for accommodating fiber, the first end directed mainly to the specified hole of the specified housing and the second end directed to the stop for the fiber located on the specified light-transmitting part of the specified base, and the specified base has a lens made in one piece with its light lowering part.  20. The socket according to claim 19, characterized in that it contains at least one active device mounted on the specified substrate and located relative to the end retainer so as to provide a functional connection with the specified light transmitting part of the specified base; and an optical plate with a lens mounted on the optical path between the specified light transmitting part of the specified base of the specified end retainer and the specified active device.

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