DE112006001379B4 - Fiber optic connector system, with markings to facilitate connectivity in four orientations for dual functionality - Google Patents

Abstract

A front cover (100) for a multi-port optical transmission system (101a-101l) arranged in at least one row, characterized in that the front cover comprises a first visual mark (104, 106) associated with the terminals, which is an array indicating in which mating optical fibers are to be inserted into the terminals, and a second visual mark (108, 110) associated with the terminals, the first visual mark comprising a text, and wherein the text on the front cover is oriented to coincide with the first horizontal and the first vertical orientation to the right is higher, and in the second horizontal and the second vertical orientation is turned upside down.

Description

Field of the invention

The present invention is generally directed to optical fiber ribbon cables, connectors, connectors and patching systems.

Background of the invention

Optical fibers are used today to transmit signals of all types, including communication and data signals. Optical fibers may be single-mode fibers (typically used in long-distance traffic) having only a strong mode, or multimode fibers where light transmitted in the various modes arrives at different times, resulting in dispersion of the transmitted signal.

Monomode fibers transmit signals between transceivers (i.e., devices that can both transmit and receive optical signals) over fiber pairs. More specifically, one fiber of the pair transmits signals from the first transceiver to the second, and the other fiber of the pair transmits signals from the second transceiver to the first. In this way, optical signals do not travel in different directions over the same fiber because such activity could cause interference of both signals.

This pair arrangement would be fairly easy to organize for two transceiver devices that are optically permanently connected, but in practice, transceivers are typically connected across a much larger network of optical fibers, connectors, and panels. For example, a typical optical system includes many transceivers at one end, patch cord pairs connected to the transceivers and to a duplex adapter mounted in a panel, a branching unit connected to the duplex adapter that connects to a multi-fiber optical cable via a group adapter (12 fibers per cable are common and the cable is often in ribbon form), a second branching unit connected to the other end of the cable via a second group adapter and corresponding transceivers connected through another duplex adapter to the second Branch unit are connected. Thus, it is clearly important to be able to follow the course of individual optical fibers in the various devices and the cables between the individual transceivers to ensure that the individual transceivers are also connected as desired.

To ensure the interoperability of cabling components and signal polarity, standards have been established to establish an array of fibers, cables, connectors, and connectors. For example, such a group connector standard, the TIA-604-5B, is directed toward the mutual adaptability of MPO light waveguides. Another standard, the TIA 568-B.3 Supplement No. 7, authored by the TR-42.8 Committee, aims to maintain fiber polarity in systems that include group connectors and connectors, including MPOs. This addition discusses three different ways of providing a beam path from the transmitting side of one transceiver to the receiving side of another transceiver. These methods, referred to as method A-C, are intended to "connect multiple duplex optical transceiver ports together or two parallel optical transceiver ports ...". Systems developed using these methods utilize fiber optic cables, connectors, transitions, and patch cords, typically uniquely assigned to one of these methods.

Each method has its own advantages and disadvantages. As such, it may be desirable to provide additional terminal methods and terminal components suitable for use in such methods.

Summary of the invention

The present invention can provide additional connectivity functionality that facilitates the use of cables and other components in optical fiber based systems. The embodiments of the present invention are directed to a front cover for an optical fiber transmission system, wherein the front cover is configured according to claim 1. This design can simplify the connection options for an operator who connects the splitter unit to a data communication system.

Brief description of the figures

1A FIG. 12 is a schematic plan view of one embodiment of a ribbon or flat cable of the present invention. FIG.

1B is a side view of the ribbon or flat cable of 1A ,

2 is a perspective view of a group adapter, the band or flat cable of 1A can be used.

3A FIG. 12 is a schematic plan view of one embodiment of a branching unit for use with the ribbon or flat cable of FIG 1A ,

3B is a side view of the termination unit of the branching unit of 3A ,

The 4A - 4D are front views of the front cover of the splitter unit of 3A and 3B which is shown in four different orientations.

5A is a schematic plan view of a data transmission system, which is a ribbon or flat cable of 1A served.

5B is a partial side view of a connection between a connection of the ribbon or flat cable and the branching unit of 5A ,

5C is a partial side view of a connection between an opposite terminal of the ribbon or flat cable and the branching unit of 5A ,

6A Figure 11 is an end view of an alternative embodiment of a front cover of a manifold unit according to the present invention with the front cover in a horizontal orientation.

6B is an end view of the front cover of 6A in a vertical orientation.

Detailed description of the embodiments of the invention

The present invention will now be described more fully hereinafter, with preferred embodiments of the invention being pointed out. However, this invention may be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, like numerals refer to like elements throughout, and the thickness of lines, layers and regions may be overstated for clarity.

It should be understood that when an element is referred to as being "coupled" or "connected" to another element, it is coupled or connected directly to the other element, but elements interposed therebetween may also be present. If, on the other hand, an element is referred to as being "directly coupled" or "directly connected" to another element, there are no intervening elements. Like numbers refer to like elements throughout. As used herein, the term "and / or" includes any and all combinations of one or more of the associated listed items.

In addition, spatial terms such as "under," "below," "lower," "above," "upper," and the like may be used. Likewise, for ease of description, it may be used herein to describe the relationship of one element or feature to another element or feature or to other elements or features as illustrated in the figures. It should be understood that the space-related terms are intended to encompass different orientations of the device in use or operation in addition to the orientations shown in the figures. For example, if the device in the figures were turned over, elements described as "below" other elements or features or "below" other elements or features would then be in alignment "above" the other elements or features. Thus, the exemplary term "under" may include both an orientation above and below. The device may also be otherwise oriented (rotated 90 degrees or in other orientations) and the space descriptive terms used herein interpreted accordingly.

For brevity and / or clarity, well-known functions and structures will not be described in detail.

As used herein, the term "and / or" includes any and all combinations of one or more of the associated listed items.

The terminology used herein is for the purpose of describing only certain embodiments and is not intended to limit the invention. As used herein, the singular forms "one, one, one," "one," and "the one," are meant to include plural forms, unless the text clearly states otherwise. In addition, it should be understood that the terms "comprises" and / or "comprising" when used in this technical description, but not individually, indicate the occurrence of identified features, integers, steps, operations, elements and / or components preclude the occurrence or addition of one or more of the features, integers, steps, operations, elements, components, and / or groups thereof.

Unless otherwise indicated, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It should also be understood that terms, such as those used in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning within the context of the relevant technical field and should not be interpreted in an idealized or overly formal sense unless it is expressly stated here.

Now, with reference to the figures, an optical fiber cable, which is broad with 10 is specified in the 1A and 1B shown. The cable 10 includes a band 12 and graduation units 15 . 15 ' at each end of the band 12 , These components will be described later in more detail.

Again with respect to 1A and 1B includes the band 12 twelve optical fibers or optical fibers 14 each of which has a core and a protective mantle. The fibers 14 are arranged in parallel relation to the tape 12 to build. Conventionally, for the sake of clarity, the fibers of a tape are individually referred to as fiber 1 , Fiber 2 , etc., directed; in the illustrated band 12 there is fiber 1 the top of 1A next, fiber 2 is below and adjacent to fiber 1 , and so on, being fiber 12 the lowest fiber in 1A is. Other conventions with the fibers 14 include color and color. and the like are set forth in TIA / EIA-598 "Optical Fiber Cable Color Coding".

The structure and composition of typical optical fibers or optical fibers is well known to those skilled in the art and need not be described in detail here. In some embodiments, the optical fibers are single-mode fibers. Exemplary optical waveguide include TeraSPEED ^™ fibers, which are available from CommScope ^® Solutions, Inc., Richardson, Texas.

It will also be clear to those skilled in the art that cables of different designs can be used. For example, cables that have tapes with different numbers of fibers can be used (6- and 8-fiber tapes are common). There can also be other fiber optic cables that have no band-like design, such as loose tube distribution cable, available from SYSTIMAX ^® Solutions, Inc., using Richardson, Texas, in connection with embodiments of the present invention.

Still referring to 1A and 1B includes the final unit 15 an end sleeve 22 that's on the tape 12 attached is a body 18 that is attached to the ferrule 22 attached, and a sleeve 16 that are on the body 18 is appropriate. The construction and mutual connection of the sleeve 16 , of the body 18 and the ferrule 22 are well known to those skilled in the art and need not be described in detail here.

Once again with respect to the 1A and 1B includes the ferrule 22 a contact surface 28 which are the fibers 14 mating fibers in a counterpart exposes. The contact surface 28 is slightly upwards and in relation to one of the axes of the fibers 14 Angled at an angle α vertical plane FS. Typically, the angle α is between about 5 and 15 degrees; For example, an angle of 8 degrees is prescribed in the TIA-604-5B for MPO connectors. In other embodiments, the contact surface 28 be parallel with the plane FS.

Still referring to the 1A and 1b includes the body 18 an adjusting wedge 26 on its upper surface. The body 18 can also be a body marker 20 (as with the in 1A schematically shown MPO connector) which provide an operator with the proper alignment of the body for assembly 18 and the ferrule 22 identifies. In the illustrated embodiment, the body mark is located 20 on the same side of a bisecting surface BS (the body 18 and the ferrule 22 halved) like the previously mentioned fiber 1 , At the body marking 20 it may be any visible mark (such as a paint mark) used by those skilled in the art to indicate the correct orientation of the termination unit 15 is considered suitable.

Still referring to the 1A and 1B includes the illustrated ferrule 22 an optional ferrule marker 24 (as with an MPO connector), which allows an operator to smooth the contact surface 28 the right alignment of the fibers 14 and the ferrule 22 identifies. The end sleeve marker 24 is at the end sleeve 22 on the side of the bisecting surface BS, that of the body mark 20 opposite, ie on the same side as the fiber 12 appropriate. The operator needs the fibers 14 so in the ferrule 22 introduce that to the fiber 12 on the same side of the ferrule 22 is like the ferrule marker 24 (this is different from a conventional fiber introduction). This point of the end sleeve marking 24 also indicates that an operator measuring the angles of the ends of the fibers 14 smoothes, the contact surface 28 so educate them Slightly upwards or slightly upwards.

Once again with respect to the 1A and 1B includes the final unit 15 ' a sleeve 16 ' , a body 18 ' and a ferrule 22 ' structurally similar to the final unit 15 are. In particular, the wedge stands 26 ' upwards, and the angled contact surface 28 ' is slightly upwards and forms an angle α 'with one to the axes of the fibers 14 when in the end sleeve 22 ' end, vertical plane. The differences between the final unit 15 ' and the graduation unit 15 include (a) the location of the body mark 20 ' on the side of the band 12 that of the fiber 12 and (b) the end sleeve marking arrangement 24 ' (if included as with an MPO connector) on the side of the tape 12 that of the fiber 1 equivalent. These arrangements cause the body markings 18 . 18 ' on opposite sides of the tape 12 located (ie on opposite sides of the bisecting plane BS and the wedges 26 . 26 ' ), and that also the end sleeve markings 24 . 24 ' on opposite sides of the tape 12 with the ferrule and body markings at each end of the cable 10 on opposite sides of their respective settlement units 15 . 15 ' are located.

Now, with respect to 2 there a MPO adapter shown, which largely with 30 is designated. The adapter 30 is not part of the present invention, but is intended for use in connection with embodiments of the present invention. The adapter 30 includes an opening 31 that passes through him. A keyway 32 extends adjacent to the opening 31 also through the adapter 30 and is sized and designed to be one of the wedges 26 . 26 ' from the cable 10 and receives a counterwedge from another component, such as a branching unit. rest 34 extend slightly into the opening to a respective termination unit 15 . 15 ' snap into place and hold. The exemplary MPO adapters and other group adapters suitable for use in connection with embodiments of the present invention are well known to those skilled in the art, and their structure and materials need not be described in greater detail herein. The exemplary MPO group adapter 30 is described in TIA-604-5B, with the exemplary adjusting wedge described as "wedge option k = 2".

Well contains with respect to the 3A and 3B a largely with 36 designated branching unit a band section 38 , the fiber optic or optical fibers 39 , a cross-section adjuster or a transition piece 54 , a graduation unit 37 , twelve single-fiber connectors 56a - 56l and a duplex adapter 62 includes. The band section 38 extends between the termination unit 37 and the transition piece 54 ; starting from the transition piece 54 the fibers separate 39 or "branch out" into pairs before joining into respective single-fiber connections 56a - 56l ends (each of the single-fiber connectors 56a - 56l is shown with its Justierkeil facing up). The mating of the fibers 39 followed a reverse sequence, in which the fibers 1 and 2 on the side of the transition piece 54 adjacent to the entrance of the fiber 12 be merged into pairs, the fibers 3 and 4 adjacent to the fibers 1 and 2 be merged into pairs, and so on, until the fibers 11 and 12 are combined into pairs. The fibers 39 are optically with the duplex adapter 62 connected, the twelve optical connections 101 - 101l Includes, on a front cover 100 in a linear grouping 102 are attached.

The final unit 37 includes a sleeve 40 , a body 42 and a ferrule 46 like those in connection with the cable 10 with the exception that the band section 38 , the ferrule 46 , the angle grind and the body 42 conventionally completed; as in an exemplary MPO connector, there are (a) the body mark 44 and the end sleeve marker 48 on the same side of the tape section 38 and the same side as the fiber 1 , and although (b) the wedge 50 from the ferrule 46 protrudes upward, the angled contact surface 52 the ferrule 46 something down. As discussed above, this alignment allows the contact surface 52 that the conclusion unit 37 the branching unit 36 with the graduation unit 15 of the cable 10 can form a unity.

The structure of this section of the branching unit 36 that the band section 38 , the transition piece 54 , the graduation unit 37 and the single fiber connectors 56a - 56l will be well known to those skilled in the art. An exemplary fan-out is available from SYSTIMAX ^® Solutions, Inc., Richardson, Texas. It will also be understood that manifold units such as so-called "hydra" units which lack a front cover can also be used with the present invention, and that the band portion 38 can be replaced by non-band-shaped optical fibers.

Now with respect to the 4A - 4D the duplex adapter 62 so at the branching unit 36 mounted that front cover 100 that in the 4A to 4D is shown, from the transition piece 54 points away. The twelve wedge sections 101 - 101l of the duplex adapter 62 take duplex plug cables 64 on (see 5A and the discussion below) and interconnect them with single fiber connectors 56a - 56l (It should be noted that the duplex adapter 62 is shown designed to, the Justierkeile the single fiber connector 56a - 56l and the plugs 64 when they point upwards). The connections 101 - 101l are arranged so that the connection 101 who's on the fiber 1 attached single fiber connector 56a picks up on one end of the linear grouping 102 located, and the connection 101l who's on the fiber 12 attached single fiber connector 56l picks up, at the other end of the grouping 102 located.

Adjacent to the end 105a the grouping 102 the connections 101 - 101l (far left in 4A ) is a visual mark 103 indicating the arrangement in which the mating optical fibers of the duplex plug lines 64 in the connections 101 - 101l should be introduced. The visual mark 103 includes a visual mark 104 , in this case the word "ALPHA", which is grouped at an angle of approximately 45 degrees 102 is arranged, wherein the beginning part of the word is lower than the end part of the word, and the letters are "higher to the right". The visual mark 103 also includes a visual mark 106 , in this case the number series "01-12", which indicates the numbers and sequence of the fibers entering the terminals 101 - 101l should be introduced. The visual mark 106 is also at an angle of about 45 degrees to the grouping 102 (ie substantially parallel to the visual marking 104 ), wherein the initial part of the visual mark 106 is lower than the end part and the numbers are "higher to the right".

At the opposite end 105b the grouping 102 (far right in 4A ) is a visual mark 107 that a visual mark 108 includes, in this case the word "BETA", which is roughly parallel with the visual marking 104 is arranged, but the letters are "turned upside down". The visual mark 107 also includes a visual mark 110 (in this case, the number series "01-12"), which is approximately parallel to the visual marking 108 is, where the numbers are "upside down".

If the front cover 100 as in 4A is arranged horizontally, with the end 105a on the left side of the duplex adapter 62 is every visual mark 104 . 106 for effortless reading by an operator "higher to the right". The visual markings 108 . 110 stand in this orientation "upside down" and are therefore difficult for an operator to read. As such, the operator can easily recognize that the branching unit 36 in this orientation circuitry is to be integrated as an "ALPHA" module.

4 represents the front cover 100 in a vertical orientation, in which the end 105a the grouping 102 up at the grouping 102 located. It can be seen that the visual marks 104 . 106 in this orientation at an angle of 45 degrees to the grouping 102 so that the beginning parts of the word "ALPHA" and the number "01-12" are higher than the end parts of the word and the number series, but so that the visual marks 104 . 106 "Higher to the right", and the visual marks 108 . 110 "Turned upside down" are. In this arrangement, the visual marks can be easily read by an operator, while that at the visual markings 108 . 110 not the case. As a result, an operator can easily recognize that it is in this orientation at the branching unit 36 to act as an "ALPHA" module.

4C represents the front cover 100 in a horizontal orientation, consisting of the in 4A rotated orientation rotated 180 degrees. In this orientation are the visual marks 108 . 110 on the left side of the grouping 102 , are "raised to the right" and can be easily read by an operator while the visual markings 104 . 106 on the right side of the grouping 102 and are "turned upside down". As a result, an operator can easily recognize that the branching unit 36 circuitry is to be incorporated as a "BETA" module.

4D represents the front cover 100 in a vertical orientation made up of the in 4B rotated orientation rotated 180 degrees. In this orientation are the visual marks 108 . 110 at the top of the grouping 102 and are "higher to the right" for ease of reading by an operator, whereas the visual marks 104 . 106 "Turned upside down" are. As a result, an operator can easily recognize that the branching unit 36 circuitry is to be incorporated as a "BETA" module.

5A provides a data transfer system 60 This is the cable 10 , two group adapters 30 and two branch units 36 . 36 ' , which are of the same construction as the type described above, but wherein the one branching unit 36 an ALPHA module and the other branching unit 36 ' is a BETA module. The system 60 also includes a number of transceivers 66 . 66 ' that are at the far ends of the system 60 (only two transceivers are shown here for clarity). With the transceivers 66 . 66 ' can be any number of devices, including computers, phones, servers, and routers that transmit optical data via Send and receive fiber optic networks. Every transceiver 66 . 66 ' is compatible with a standard pair of TIA / EIA-568-B.3 compliant patch cords 64 . 64 ' connected. The transceivers 66 . 66 ' are so to the plug lines 64 . 64 ' connected so that the adjustment wedges point upwards. The plug cables 64 . 64 ' (which in this case are duplex patch cords, but in other embodiments may be single fiber or other multi-fiber cabling) are in turn with ports in one of two duplex adapters 62 . 62 ' connected, whose structure is the same and as described above. The single fiber connectors 56a - 56l each branching unit 36 . 36 ' be pairwise as described above and in the 5A - 5C shown in a respective duplex adapter 62 . 62 ' plugged in. The branching units 36 . 36 ' are about the group adapters 30 with the graduation units 15 . 15 ' of the cable 10 connected.

Regarding 5A it can be seen that the trunk cable " 10 "Includes a" twist "that causes the termination unit 15 with their adjusting wedges 26 is placed facing up, and the termination unit 15 ' is arranged so that you adjusting wedge 26 ' pointing down. This "twist" can be achieved in any number of ways; it does not physically distort the cable 10 but instead simply provides the reverse orientation of the termination units 15 . 15 ' if they have a mating relationship with their respective branching units 36 . 36 ' The "twist" also has the effect of aligning the fibers 14 in the cable 10 at the final unit 15 ' to reverse so that when the Justierkeil 26 ' extends downwards, one of the contact surface 28 ' of the final unit 15 ' facing the fiber 12 on the left side of the contact surface 28 ' and the fiber 1 on the right side of the contact surface 28 ' would see.

Although the branching units 36 . 36 ' and the associated duplex adapters 62 . 62 ' structurally identical, they are in a visually reversed way with the termination units 15 . 15 ' connected so that they have an "ALPHA" module and a "BETA" module for interconnection with the patch cords 64 . 64 ' represent. As in 5A is shown, all adjustment wedges are the single fiber connector 56a - 56l the branching unit 36 in the connections 101 - 101l of the duplex adapter 62 inserted facing up. Also are the fibers 1 - 12 the branching unit 36 from the perspective of one of the front cover 100 of the duplex adapter 62 facing person in ascending order from left to right strung. In this arrangement are the visual marks 104 . 106 the front cover 100 on the left side of the front cover 100 and are "higher to the right," indicating that this is an ALPHA branch unit. Thus, the plug lines 64 in ascending order in the ports 101 - 101l plugged in (ie fiber 1 in the far left position to pair with the fiber 1 the branching unit 36 to enter, and fiber 12 in the very right position to with the fiber 12 the branching unit 36 to make a pairing), with their Justierkeile turned upwards.

By contrast, all adjusting wedges are the single fiber connectors 56a ' - 56l ' the branching unit 36 ' into the connections of the duplex adapter 62 ' plugged down, and the fibers 1 - 12 are (from the viewpoint of one of the front panel 100 facing person) in descending order from left to right. When comparing this arrangement with 4C can be seen that this orientation of the branching module 36 ' the visual markings 108 . 110 on the left side of the front cover 100 and positioned "higher to the right", causing the branching unit 36 ' is qualified as a "BETA" module. Thus, the plug lines 64 ' in descending order (ie the fiber 1 in the very right position to make a pairing with the fiber 12 the branching unit 36 ' to enter, and the fiber 12 in the very right position to make a pairing with the fiber 1 the branching unit 36 ' to enter) with its adjusting wedges turned turned down. The plug cables 64 ' are shown with a "twist" between their ends to connect "wedge up to wedge up" with the transceiver 66 ' display.

As in the 5A and 5B is shown, the connections between the branching units 36 and the graduation units 15 . 15 ' of the cable 10 around "wedge up on wedge up" or "wedge down on wedge down", which tends to be preferable from a performance standpoint. The design described here allows the angle ground contact surfaces 28 . 28 ' the graduation units 15 . 15 ' a fitting connection with the angle-ground contact surfaces 52 the branching units 36 . 36 ' can enter. The mating engagement of these angled contact surfaces provides transmission of optical data in a manner typically superior to that of non-angled (ie, flat) contact surfaces, and accomplishes this with a "wedge up wedge up" or "wedge down" orientation at wedge down "the closing body 18 . 18 ' of the cable 10 and the closing body 42 the branching units 36 (please refer 5B ). Above all, one of the two final units 15 . 15 ' with one of the two branching units 36 . 36 ' be connected and still be functional.

It can be verified if the system 60 actually provides a proper connectivity for optical signals by keeping track of transmission paths between a pair of attached transceivers 66 . 66 ' is traced. Regarding 5B and to the transmitting section Tx of the transceiver 66 beginning, there would be an originating optical signal through the patch cord 64 that comes with "fiber 2 "To the duplex adapter 62 run. The signal would then make its way through the signal fiber connector 56b in the fiber 2 the branching unit 36 take that signal to the group adapter 30 forwards. At this point, the signal passes through the termination unit 15 to the fiber 11 of the cable 10 transfer that with the fiber 2 the branching unit 36 is aligned. The signal passes through the cable 10 in the fiber 11 to the final unit 15 ' , through the second group adapter 30 and in the second branching unit 36 ' where it s.der fiber 11 is transmitted. The signal then passes in the fiber 11 the second branching unit 36 ' through the single fiber connector 56b ' , the duplex adapter 62 ' , the fiber 11 of the plug line pair 64 ' and in the receiving section Rx of the transceiver 66 ' , Thus, the signal from the transmitting section of the transceiver 66 properly to the receiving section of the transceiver 66 ' transfer.

Continue with reference to 5A can the course of a parallel transmission path from the transmitting section Tx of the transceiver 66 ' to the receiving section Rx of the transceiver 66 be tracked. More specifically, the signal is from the transmit section Tx of the transceiver 66 ' through the fiber 12 of the plug line pair 64 ' through the duplex adapter 62 ' in the fiber 12 the second branching unit 36 ' , through the second group adapter 30 in the fiber 12 of the cable 10 , through the first group adapter 30 and in the fiber 1 the first branching unit 36 , and through the duplex adapter 62 in the fiber 1 of the plug line pair 64 to enter the receive section Rx of the transceiver 66 to be delivered. Thus, it can be seen that the signal from the transmitting section Tx of the transceiver 66 ' properly to the receiving section Rx of the transceiver 66 is transmitted.

The professionals in the field will also realize that the cable 10 can be designed so that, rather than the contact surfaces 28 the end sleeves 22 . 22 ' something upwards are, even the tape 12 can be aligned so that the contact surfaces 28 something are turned down while the wedges 26 still projecting upwards. Such modification would be branching units 36 use that have contact surfaces that are slightly upwards when their wedges 50 extend upwards.

Those skilled in the art will also appreciate that the present invention can be used with multiple fiber optic cables. Now, with respect to 6 there a duplex adapter 162 with a front cover 200 shown. At the front cover 200 is a grouping 202 of connections 201 - 201l and 203a - 203l housed, which are arranged in two rows. In this embodiment, each of the terminals is 201 - 201l aligned so that it receives a Justierkeil of a mating connector which extends downwards, and each of the terminals 203a - 203l is aligned so that it receives a Justierkeil of a mating connector, which extends upwards. The front cover 200 includes a visual mark 204 that look like the visual mark 104 the front cover 100 indicates an "ALPHA" module and also includes visual markings 206a . 206b introducing the fibers 1 - 12 in the connections 203a - 203l in ascending order and introducing the fibers 13 - 24 in the connections 201 - 201l specify in ascending order.

visual markings 208 . 210a . 210b are at the opposite end of the front cover 100 positioned and are analogous to the visual markings 108 . 110 the front cover 100 , It can be seen that when the duplex adapter is in the orientation of 6 is located, the visual marks 204 . 206a . 206b read and inform an operator that this is an ALPHA module and that the visual markings 208 . 210a . 210b difficult to read. The same would apply if the front cover 200 from the in 6 position rotated 90 degrees clockwise. Would the front cover 200 from the position of 6 however, rotated by 180 or 270 degrees, the visual marks could 208 . 210a . 210b read more easily by an operator who would then realize that this must be a BETA module.

Professionals in the field will recognize that, although the front cover 100 is designed to accommodate 12 fibers from a cable, and the front cover 200 is designed to accept 24 fibers from two cables (12 from each cable), the front covers may also be configured to accommodate any number of cables (eg, four or eight cables). Also, the front covers may be configured to accept different numbers of fibers per cable, although even fiber counts (ie, fibers in pairs) are most typical.

Those skilled in the art will recognize that other data communication systems may use the trunk cables of the present invention with jigs. Exemplary alternative systems include harsh operating conditions, that is, robust group connector / single fiber junction units comprising the branching units 36 and 36 ' , the duplex adapter 62 and 62 ' and the duplex adapter cables 64 and 64 ' replace that in 5A are shown.

The foregoing is illustrative of the present invention and is not to be construed as limiting it. Although exemplary embodiments of this invention have been described, those skilled in the art will readily appreciate that many modifications may be made to the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to be included within the scope of this invention as set forth in the claims. The invention is defined by the following claims, wherein equivalents of the claims are intended to be included therein.

Claims (5)

Front cover ( 100 ) for an optical fiber transmission system, with several connections ( 101 - 101l ) arranged in at least one row, characterized in that the front cover has a first visual marking ( 104 . 106 ) associated with the terminals, indicating an arrangement in which associated optical fibers are to be inserted into the terminals, and a second visual marking ( 108 . 110 ) associated with the terminals, the first visual mark comprising a text, and wherein the text on the front cover is oriented to be higher in the first horizontal and first vertical orientations to the right, and in the second horizontal and vertical directions second vertical orientation is turned upside down. A front cover according to claim 1, wherein the first visual mark is disposed at an angle of about 45 degrees to an axis formed by the row of terminals. A front cover according to claim 2, wherein the first visual marking is a textual word ( 104 ), which indicates the orientation of the front cover, and a number series ( 106 ) indicating the arrangement of the mating fibers in the terminals. The front cover of claim 1, wherein the front cover comprises two rows of terminals. A front cover according to claim 1, wherein the first visual marking is a textual word ( 104 ), which indicates the orientation of the front cover, and a number series ( 106 ), which indicates the arrangement of the associated fibers in the terminals, and wherein the second visual marking is a textual word ( 108 ), which indicates the orientation of the front cover, and a number series ( 110 ), which indicates the arrangement of the mating fibers in the terminals, and wherein the text words of the first and second visual marks are different, and the rows of numbers of the first and second visual marks are the same.

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