DE20115940U1 - Light waveguide distribution slot - Google Patents

Description

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Fiber optic distribution insert

The invention relates to an optical fiber distribution insert according to the preamble of claim 1.

A generic fiber optic distribution insert is known from DE 197 50 932 and is used to separate a loose tube, which has a plurality of fiber optic cables, and to connect it to fiber optic cables that lead to individual terminal devices. The fiber optic distribution insert consists of a flat cassette carrier that can be inserted vertically into a module carrier. A front plate is attached to the front of the fiber optic distribution insert, which has a plurality of feedthroughs for fiber optic cables that connect the individual terminal devices to the system technology of the network. Parallel to the flat cassette carrier, cassettes can be attached next to each other on both sides, which can be designed as splice, overlength or loose tube feed cassettes.

In a splice cassette, the individual optical fibers of a loose tube are spliced individually to so-called "pigtails" and led to sockets. Alternatively, the individual optical fibers can be led directly through a feedthrough in the front panel. The loose tube coming from the system technology is led from the rear to the optical fiber distributor insert and inserted into the splice cassette.

In order to be able to pull the fiber optic distribution insert out of the subrack for initial installation and to carry out repairs or subsequent installation work, it is advisable to provide a working or splicing reserve for the loose tube placed in a loop, which increases its diameter when the fiber optic distribution insert is pushed in after installation and reduces its diameter again when pulled out. In addition, this working and splicing reserve can also be used to create new splice connections. The loose tube feed cassette is designed for this purpose.

This has a drum-shaped radius limiter inside, onto which the working and splicing reserve is wound in the form of a loop when the cassette carrier is pulled out of the module carrier, which relaxes again after the fiber optic distribution insert is inserted.

The loose tube wound up in this way is then passed over and inserted in an arc outside the loose tube feed cassette into the adjacent cassettes.

From EP 0 617 304 it is known to provide the base plates of the individual cassettes, for example an overlength cassette, with feedthrough openings through which an optical waveguide laid in a loop can be introduced directly into an adjacent cassette without it having to be guided in a curve outside the cassette.

Since optical fibers can only be routed in loops or bends without being damaged, provided that they do not fall below a certain minimum bending radius, the loose tube launch cassette must have a minimum size in order to be able to accommodate the loose tube laid in loops. Since a greater length of the loose tube must be accommodated in the loose tube launch cassette, the radius of the loop resulting when inserted into the module carrier is relatively large, so that in the subject matter of DE 197 50 932 the loose tube launch cassette has enlarged external dimensions.

It is an object of the invention to provide an optical fiber distribution insert with a loose tube launch cassette whose dimensions essentially correspond to those of the other standard cassettes.

The object of the invention is achieved by the invention specified in claim 1. Preferred embodiments of the invention are specified in the subclaims.

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The generic optical fiber distribution insert has a cassette carrier with a carrier plate that can be inserted into a module carrier and to which a front plate is detachably attached, wherein a plurality of cassettes can be attached to both sides of the carrier plate of the cassette carrier, via which a loose tube can be connected to further individual optical fibers, wherein a loose tube feed cassette has an annular channel for receiving a loose tube. According to the invention, the optical fiber distribution insert is characterized in that the loose tube feed cassette has essentially the same external dimensions as the carrier plate and the other cassettes, and that the loose tube feed cassette is provided with side openings through which sections of the loose tube laid in a loop in the loose tube feed cassette can emerge from the loose tube feed cassette in a radial direction.

During assembly of a loose tube, it is wound tightly onto the radius limit of the loose tube launch cassette of a fiber optic distribution insert that has been pulled out of the assembly carrier. After assembly is complete, the working and splicing reserve placed in a loop is compressed during insertion of the fiber optic distribution insert into the assembly and can therefore expand in the radial direction. In the invention, this process is not limited by the size of the loose tube launch cassette, since the compressed working and splicing reserve can exit through the side openings. Loose tube launch cassettes with openings according to the invention can therefore be designed smaller than loose tube launch cassettes without openings, so that the loose tube launch cassette according to the invention does not have to be designed larger than the carrier plate and the other cassettes.

Preferably, the base plates of the excess length and/or splice cassette have feedthrough openings through which optical fibers can be guided from a first cassette into an adjacent second cassette.

By providing feedthrough openings, it is possible to dispense with curved sections of the optical fibers, since instead the optical fibers can be led from one cassette to the other cassette through the feedthrough openings directly into an adjacent cassette, so that the optical fibers are no longer partially unprotected outside the cassettes. In addition, the installation depth of the optical fiber distributor insert can be further reduced.

In a preferred embodiment, the carrier plate of the cassette carrier has a recess on the edge, which forms a passage with the through openings of cassettes arranged on both sides of the carrier plate, through which optical waveguides can be transferred from a cassette arranged on the first side of the carrier plate to a cassette arranged on the second side of the carrier plate.

The recess in the carrier plate also makes it possible to dispense with curved sections, since they form a passage with the through openings of the cassettes, which are attached to both sides of the carrier plate, through which optical fibers can be guided from a first cassette into a second cassette, which is attached to the opposite side of the carrier plate. In addition, the recess in the carrier plate simplifies the removal of cassettes with spliced connections that are attached to the carrier plate, for example to carry out repairs, since the spliced connections can simply be removed from the recess while the cassettes are being detached from the carrier plate.

In a further embodiment, the front panel is designed in several parts and is composed of at least one plug plate for receiving plug sockets and one fixed wire feedthrough plate for passing through optical fibers. The front panel can thus advantageously be easily adapted to the respective requirements and needs with regard to the number of plug sockets or fixed feedthroughs.

Preferably, the tight-wire feedthrough plate has a series of holes that are guided via a gap to the edge of the tight-wire feedthrough plate, so that spliced optical fibers that are provided with a feedthrough and anti-kink sleeve can be guided out of the tight-wire feedthrough plate at the side and thus detached from the tight-wire feedthrough plate.

In the following, the invention is explained in more detail with reference to the drawing, in which

Fig. 1 shows a perspective view of a fiber optic distribution insert according to the invention in the assembled state, and

Fig. 2 shows a perspective exploded view of an optical fiber distribution insert according to the invention.

Reference is made to Figs. 1 and 2.

The fiber optic distribution insert contains a flat cassette carrier 2 with a carrier plate 14 made of metal or plastic, which is preferably 100 mm high and 190 mm long and can be inserted and pushed vertically into an upper and lower rail of a module carrier. A front plate 9 made of anodized aluminum is attached to the carrier plate 14, preferably with the aid of brackets, which is preferably 128.7 mm high and 76 mm wide and whose plane is arranged at right angles to the plane of the carrier plate 14.

The front panel 9 consists of a connector plate 10 and a tight-wire feedthrough plate 11 and can be divided into two parts. Up to twelve couplings 22 can be located on the connector plate 10, whereby various designs are possible with which optical fibers can be coupled, while the tight-wire feedthrough plate 11, on the other hand, has up to twelve feedthroughs 24 through which individual optical fibers can be fed. Since both the

Since both the plug plate 10 and the tight-wire feedthrough plate 11 can be attached to the cassette carrier 2 individually or in combination, it is possible to exchange and combine plug plates 10 and tight-wire feedthrough plates 11 as required.

The tight-buffer feedthrough plate 9 has a series of holes 24 which are guided via a gap to the edge of the tight-buffer feedthrough plate 9 so that spliced optical fibers which are provided with a feedthrough and anti-kink sleeve can be guided laterally out of the hole 24 until they have reached the edge of the tight-buffer feedthrough plate 9 and are detached from it.

Cassettes 1, 3, 7 are detachably attached to the carrier plate 14 of the carrier cassette 2 on both sides, with the cassettes 1, 3, 7 being arranged vertically next to one another on one side, while only a single cassette 3 is attached to the opposite side of the carrier plate 14. The individual cassettes 1, 3, 7 are designed as a loose tube feed cassette 1, as an overlength cassette 3 and as a splice cassette 7, the external dimensions of which are essentially identical, with the individual cassettes 1, 3, 7 being attached to the carrier plate 14 or to adjacent cassettes 1, 3, 7 without any offset to one another and to the front plate. Two cassettes (1, 3, 7) lying next to one another can also be connected to one another by swivel joints, so that an outer cassette can be folded down, for example to enable installation work on an inner cassette.

In the splice cassette 7, the optical fibers of a loose tube are guided in a curve, separated and connected via pigtails to individual sockets on the plug-in board 10. In the loose tube feed cassette 1 and the excess length cassette 3, a loose tube laid in a loop or individual optical fibers are accommodated, which serve as a working and splicing reserve, whereby this reserve is wound on a drum-shaped radius limiter 18 located inside the feed and excess length cassettes. In addition, guide means 20 are arranged in a circle around the radius limiter 18, which are connected to the

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Radius limitation 18 forms an annular guide channel in which the relaxed working and splicing reserve can be accommodated.

The loose tube launch cassette 1 has a lower and upper side opening 4. Through these openings 4, a working and splicing reserve of a loose tube laid in a loop can expand radially, which is wound tightly onto the radius limit when the fiber optic distribution insert is pulled out of the assembly. After the work has been carried out, the fiber optic distribution insert is pushed back into the assembly. The working and splicing reserve laid in a loop is compressed and expands radially accordingly, whereby it can emerge from the loose tube launch cassette 1 in the area of the openings 4.

The base plates 3a, 7a of the excess length cassette 3 and the splice cassette 7 are each provided with a feedthrough opening 6, which are arranged in the base plate section of the annular channel, so that they form a passage between two cassettes 3, 7 arranged next to one another, through which an optical fiber accommodated in the guide channel can be led out and thus transferred from one cassette to the adjacent cassette. In order to protect the interior of the cassettes 3, 7 from contamination, the cassettes can be closed with removable covers 12.

The carrier plate 14 of the cassette carrier 2 has a recess 8 on the edge, which is positioned and dimensioned in such a way that it forms a passage for the passage of optical fibers with the passage openings 6 of the cassettes 3, 7, which are fastened to the carrier plate 14. The recess 8 allows cassettes 3, 7 fastened to the carrier plate 14 with optical fiber connections guided through the recess 8 to be easily removed, since these optical fibers can simply be taken out of the recess 8 and placed back into the recess 8 after work has been completed.

To establish a switching connection starting from a loose tube, first the loose tube launch cassette 1 and then the overlength cassette 3, which is on

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Screw bolts are seated, so that the interior of the splice cassette 7 is freely accessible. The loose tube is then inserted into the splice cassette 7 and fixed to it, and the individual optical fibers are spliced using so-called pigtails. The excess length cassette 3 and the loose tube feed cassette 1 are then placed back on the carrier plate 14. The loose tube is now inserted into the loose tube feed cassette 1 and wound tightly onto the radius limit 18. Finally, the optical fiber distributor insert is pushed into the assembly, with the loose tube being compressed during this movement and expanding radially, partially extending through the side openings 4 from the loose tube feed cassette 1.

To create a permanent connection, the fiber optic distribution insert is first pulled out of the subrack, whereby the compressed loose tube contracts and, when the pulled-out position is reached, rests tautly against the radius limit again. Next, the loose tube is unwound from the core of the loose tube launch cassette 1. Then both the loose tube launch cassette 1 and the excess length cassette 3 are removed so that the desired splice connection can be easily reached and separated. A switch cable is then fed through a hole 24 in the front plate 9 and fixed in the hole 24 with a feed-through and anti-kink grommet and fed through the feed-through opening 6 of the excess length cassette 3 into the splice cassette 7. The switch cable is then attached to the splice cassette 7 and spliced to an optical fiber of the loose tube. Now the excess length cassette 3 is put on and the switching cable is inserted in a loop into the excess length cassette 3. Finally, the loose tube launch cassette 1 is put back on, the loose tube is also inserted into the loose tube launch cassette 1 and the fiber optic distributor insert is inserted into the module carrier, whereby the winding radius of the loose tube increases again during insertion and the loose tube finally extends through the side openings 4 in the inserted state.

Reference list 1 Loose tube launch cassette 2 Cassette carrier 3 Overlength cassette 3a Base plate of the overlength cassette 4 opening 6 Feedthrough opening 7 Splice cassette 7a Base plate of the splice cassette 8th Recess 9 Front panel 10 Plug plate 11 Tight buffer feedthrough plate 12 cover 14 Carrier plate 18 Wheel in usb connection 20 Management tools 22 Couplings 24 drilling

Claims (5)

1. Optical fiber distributor insert, in particular for connecting loose cores to individual optical fibers to be continued, with a cassette carrier ( 2 ) with a carrier plate ( 14 ) which can be inserted into a module carrier and to which a front plate ( 9 ) is detachably fastened, wherein a plurality of cassettes ( 1 , 3 , 7 ) can be fastened to both sides of the carrier plate ( 14 ) of the cassette carrier ( 2 ), via which loose cores can be connected to individual optical fibers to be continued, wherein a loose core feed cassette ( 1 ) has an annular channel for receiving a loose core, characterized in that the loose core feed cassette ( 1 ) has essentially the same external dimensions as the carrier plate ( 14 ) and the other cassettes ( 3 , 7 ), and that the loose core feed cassette ( 1 ) is provided with lateral openings ( 4 ) through which sections of the loose tube laid in a loop in the loose tube feed cassette ( 1 ) can emerge from the loose tube feed cassette ( 1 ) in a radial direction. 2. Optical fiber distributor insert according to claim 1 with a splice cassette ( 7 ), characterized in that the base plates ( 3a , 7a ) of the excess length and/or splice cassette ( 3 , 7 ) have feedthrough openings ( 6 ) through which optical fibers from a first cassette ( 3 , 7 ) can be guided into an adjacent second cassette ( 3 , 7 ). 3. Optical fiber distributor insert according to claim 1 or 2, characterized in that the carrier plate ( 14 ) of the cassette carrier ( 2 ) has a recess ( 8 ) on the edge, which forms a passage with the feedthrough openings ( 6 ) of cassettes ( 3 , 7 ) arranged on both sides of the carrier plate, through which optical fibers can be transferred from a cassette ( 3 , 7 ) arranged on the first side of the carrier plate ( 14 ) into a cassette ( 3 , 7 ) arranged on the second side of the carrier plate ( 14 ). 4. Optical fiber distributor insert according to one of the preceding claims, characterized in that the front plate ( 9 ) is designed in several parts and is composed of at least one plug plate ( 10 ) for receiving plug sockets and a fixed wire feedthrough plate ( 11 ) for passing through optical fibers. 5. Optical fiber distribution insert according to claim 5, characterized in that the tight-wire feedthrough plate ( 11 ) has a series of holes ( 24 ) which are open towards the edge of the tight-wire feedthrough plate ( 11 ).