WO2005045487A2

WO2005045487A2 - Housing for optical components

Info

Publication number: WO2005045487A2
Application number: PCT/DE2004/002370
Authority: WO
Inventors: Norbert Meyers
Original assignee: Bktel Communications Gmbh
Priority date: 2003-10-30
Filing date: 2004-10-23
Publication date: 2005-05-19
Also published as: DE10350954A1; WO2005045487A3; EP1678542A2

Abstract

The invention relates to a housing comprising an input port for a light wave guide cable and a plurality of parallel output ports. At least one optical signal-processing component, a light wave guide strip with a predetermined bending radius of preferably at least 30 mm and optical connectors are located in the interior of the housing, interposed between the input port and the output ports. According to the invention, the input port, the light wave guide strip and at least one optical connector are stationarily mounted as an interface on a base plate unit. At least one component for signal processing, one or more signal converters for transforming the signal and at least one optical connector and the output ports are disposed in a housing cover that is detachably linked with the base plate unit.

Description

Housing for optical components

The invention relates to a housing with an input port for an optical waveguide cable and with a plurality of parallel output ports, wherein at least one optical signal processing assembly, an optical waveguide band with a predefinable bending radius of preferably at least 30 mm and optical connectors are arranged inside the housing between the input port and the output ports are.

The importance of optical fibers in media technology is growing to the extent that a simultaneous transmission of different data formats as an audio, video or other control signal is desirable. Long transmission lines can also be implemented with optical fibers without significant losses. Compared to conventional metal cables, the optical fibers not only have a significantly lower weight, but the costs per transmitting channel can also be minimized. In addition, optical fibers have a high level of security against eavesdropping and are not at risk from lightning like metal cables. With optical fibers, low attenuation values, large transmission bandwidths with a high signal density and largely frequency-independent line attenuation of the signals to be transmitted can be achieved with minimal installation effort. The transmission rates through multiple carrier waves can be expanded almost indefinitely.

An optical fiber cable consists of several fibers, which in turn have a core, a jacket and a coating. The light-guiding core is used for signal transmission. The coating ensures protection of the core against mechanical damage. The cladding, which consists of a different glass fiber than the core, is also light-guiding, but has a lower refractive index, which enables total reflection and thus light beam guidance in the core. Usual core diameters are 9 μm, the shell 125 μm and the coating up to 1 mm. The connection of two optical fiber ends is carried out by means of a splicer. There the ends are connected to one another by fusing, for example under an arc. The (splice) connection is provided with a protective cover (splice protection) so that this connection point can be adequately protected against mechanical loads such as tension, bending, corrosion and environmental influences. For a division of individual signal lines into different optical components, detachable connectors are also used, which consist of two optical fiber connectors, which are usually connected to one another by means of a guide coupling. When transmitting signals in such a connector, it must be ensured that the ends of the two fibers are brought close together in order to ensure undisturbed signal transmission. In any case, the size of the air gap between the two fiber end faces (fiber ends) increases the damping.

In addition, in order to process the optical signals, the signal distribution and the signal conversion (into electrical signals), further components are required, which are not only to be arranged in an orderly manner, but also to be arranged in a sealed housing. The fiber optic cable arriving in a house basement, for example, is laid to a housing with an input port (with a pull-down resistant hold-down device), with excess lengths being provided as line reserves as a precaution. Basically, it is known from the prior art to arrange corresponding optical waveguide tape guides, splice connections, plug receptacles, transceivers, splitters and all other components required in such a housing.

With such an optical fiber cable, however, a wealth of data is made available in the house, which is not desired by every resident of this house due to the high total price. Until it is activated after the contract has been signed, it is even desirable that the residents do not use data unauthorizedly via existing or created output ports of the housing. It is therefore an object of the present invention to provide a housing of the type mentioned at the outset which, on the one hand, provides adequate mechanical protection for the modules located between the input port and the output port or the output ports, and on the other hand creates the possibility of manipulation by unauthorized persons from the outset avoid.

This object is achieved by the housing according to claim 1. According to claim 1, the input ports, the optical waveguide band and at least one optical connector are arranged permanently mounted on a base plate unit, whereas at least one module for signal processing, one or more signal converters for converting the signals and at least one optical connector and the output ports are arranged in a housing cover are, which is detachably connected to the base plate unit, preferably via a tongue and groove connection and / or a snap or snap lock. This creates the possibility of installing the floor slab unit in a residential building as a precaution and regardless of whether the incoming data is later used in whole or in part by appropriate signal processing and conversion. The base plate unit can be closed on the front by a simple cover plate. The resident or residents of the relevant residential building who decide to use the data and who are willing to pay the usage fees for the provision of the data in accordance with the desired scope of use will be given the correspondingly equipped housing cover when the contract is concluded, which will then be released after the cover plate has been removed who can assemble the housing cover that is equipped according to the actual use. Before this, only the optical connectors have to be coupled to one another in order to ensure a signal transition.

The base plate unit and the housing cover are preferably at least essentially closed except for a recess necessary for the accessibility of the optical plug connectors. With this measure, the individual components are secured against mechanical damage to the outside. When using molded plastic parts or sheet metal parts is also Manipulations are prevented, since the covered optical assemblies cannot be reached without destroying the plastic or sheet metal walls surrounding them.

According to a further embodiment of the invention, the plug connectors are arranged in the base plate unit and in the housing cover in such a way that when the housing cover is guided up to the connection state, the plug connectors can be brought into the contact position required for a signal line at the same time. For this purpose, the mutually complementary plug connectors preferably have a socket part and a plug part, which have conically shaped surfaces for centering. According to the prior art, fiber optic plug connections consist of two plugs which are connected to one another via a guide coupling. Such a connection requires precise work in order to optimally align the two fibers, whose end faces are to be brought together as close as possible to one another. Every radial and axial displacement affects the transmission or increases the damping that occurs. Alone in order to be able to save the previously required guide coupling, therefore, according to the present invention, one plug part is designed as a socket, while the other plug part is designed as a complementary part to the socket as a real plug, which is centered over existing conical guides in such a way that the optical fiber contained therein comes in a coaxial position to the optical fiber of the socket part at the plug connection. Appropriate stops or catches, which are known in principle in connection technology, can also be used to ensure that a reproducible, narrow air gap is always set between the opposing end faces of the optical waveguide when plugged in. The measures described above not only simplify the handling of the plug connection, but also the assembly of the base plate unit with the housing cover. In a preferred exemplary embodiment, the housing cover is aligned with corresponding guides with respect to the base plate unit and then the housing cover is moved transversely to the base plate unit without any further change in distance, the desired connection of the optical plug and of the two housing parts being produced at the same time. about Stops or a snap connection of the two housing parts ensures that the possible transverse sliding movement is limited.

According to a further embodiment, the base plate unit and / or the housing cover have exchangeable plug-in transducers and / or a transmitter / receiver unit (transceiver). This measure simplifies the storage, since basic modules can be defined both for the base plate unit and for the housing cover, which are then equipped with the converter or the transceiver before delivery, depending on the requirements. The converter or converters can preferably be inserted via a comb connector.

As is known in principle from the prior art, the fiber reserve is wound up in a substantially circular manner via corresponding guides, holders or protective channels in the edge region of the housing, according to the invention in the edge region of the base plate unit, in order to be able to guarantee a correspondingly large bending radius for the glass fiber cables.

According to a further embodiment of the invention, splices, optical plugs, splitters, taps and / or wavelength multipliers are attached to the inside of the base plate unit, preferably detachably via plug connections (insofar as this is expedient in the form of inexpensive storage).

An embodiment of the invention is shown in the drawings. Show it:

1 is a perspective view of a housing cover,

2 is a perspective view of a base plate unit,

Fig. 3 is a perspective view of an optical connector as well

Fig. 4 is a perspective view of a converter module. The housing according to the invention consists of the parts shown in FIGS. 1 and 2, namely a housing cover 10 and a base plate unit 11, which can be detachably connected to one another via projecting hooks 12 in connection with corresponding recesses and undercut areas in the housing cover. For the sake of clarity, components known per se, such as glass fibers, couplers and splices, as well as the detailed structure of the input port and the output ports suitable for plug connections with corresponding hold-down devices are omitted. In the simplest case, an optical fiber comes from an inserted optical fiber cable. The glass fiber excess length is wound up in a substantially circular manner in the edge region of this unit via corresponding holders or protective channels in the base plate unit. A glass fiber splice connects the wound fiber with a pigtail, consisting of a short fiber with an attached optical connector. The optical plug 13 (see FIG. 3) is fastened in a holder on the floor or on the inside of the base plate unit. However, the one or more glass fibers can also be split onto several glass fibers via one or more optical splitters or taps and / or wavelength multipliers, which then open into several glass fiber connectors and are fastened to the base plate unit. Wavelength multiplexers can be used to distribute different wavelengths to different glass fibers, which are then routed to separate optical transceivers, transmitters and / or receivers via several connectors.

The base plate unit 11 is screwed, for example, to a wall in a residential building. As long as no subscriber connections are required or desired in order to use the telecommunications or data network provided, the base plate unit is covered by a simple housing plate on the front. This plate only serves to protect the passive optical components in the interior of the base plate unit against mechanical damage and / or contamination. The plate can be attached in the same manner as described below for the housing cover. On its invisible underside, the housing cover has four slots in the edge area through which the hooks 12 can be pushed. By shifting the housing cover 10 transversely relative to the base plate unit 11 (in the present case to the left), the hooks 12 undercut corresponding undercuts in the housing cover. Either the hook itself or other stops or locking means limit the possible displacement.

In the illustrated case, the converter module 14, which is detachably fastened in the housing cover by means of an electrical plug connection 15 (see FIG. 4), projects beyond the underside of the housing cover. This converter module has openings designed as sockets 16, which have conical bevels as centering aids for the plugs 17 of the optical plug 13 (see FIG. 3). Two optical fiber lines 18 are shown as an example in FIG. 3 on the optical connector 13. The converter module and the optical plug are arranged in the housing cover 10 or the base plate unit 11 in such a way that the plugs 17 can be guided past the sockets 16 at a small distance when the hooks 12 are inserted into corresponding recesses in the housing cover. With the transverse displacement of the housing cover 10 (in the picture to the left), the plugs 7 slide into the sockets 16. When the stop formed by the hooks 12 is reached, the plug connection between the optical plug 13 and the converter 14 is brought about at the same time.

In this embodiment, the manual connection of two optical plugs with the aid of a guide sleeve is thus eliminated. In the context of the present invention, it is of course possible to manually connect plugs provided in each case on the ends of the optical fiber cable, both in the housing cover and in the base plate unit; in this case, two slots are preferably provided in the small end face 20 of the housing cover, through which the hooks 12 shown on the left in FIG. 2 can be guided and locked in order to hold the housing cover during the assembly of the optical connector. An optical connector (either in the housing cover or the base plate unit) is expediently firmly connected to the housing part, whereas the complementary optical connector is designed as the end of a loosely guided cable.

Insofar as is necessary or desired in terms of cheaper storage, the passive optical components can be fixed or detachably connected to the housing part in question, the latter embodiment variant having the advantage of a flexibly manageable modular structure.

In any case, the core idea of the present invention is that the base plate unit serves as a holder for the incoming optical waveguide and for accommodating the optical waveguide cable reserves as well as for accommodating basic modules, which are indispensable for signal line and processing, but due to the lack of signal conversion into electrical signals do not allow the use of the telecommunications or data network. In order to create this possibility of use, the end user can purchase a module which corresponds to his needs and which is connected to the base plate unit in the manner described above. The desired and processed data signals are then available at the output sockets (not shown). No special experience or specialist knowledge is required to install the housing cover.

Claims

claims

1.Housing with an input port for an optical waveguide cable and with a plurality of parallel output ports, wherein at least one optical signal processing assembly, an optical waveguide band with a predefinable bending radius of preferably at least 30 mm and optical plug connectors are arranged inside the housing between the input port and the output ports, characterized in that the input port, the optical waveguide band and at least one optical connector are permanently mounted as an interface on a base plate unit (11) and that at least one module for signal processing has one or more signal converters for converting the signals and at least one optical connector and the output ports in one Housing cover (10) are arranged, which is detachably connected to the base plate unit, preferably via a tongue and groove connection and / or a snap or snap lock.

2. Housing according to claim 1, characterized in that the base plate unit (11) and the housing cover (10) are at least substantially closed except for a recess necessary for the accessibility of the optical connector.

3. Housing according to claim 1 or 2, characterized in that the connectors in the base plate unit (11) and in the housing cover (10) are arranged such that when the housing cover is guided up to the connection state, the connectors (17, 18) simultaneously in the contact position required for a signal line can be brought.

4. Housing according to claim 3, characterized in that the mutually complementary connectors have a socket part (16) and a plug part (17) which have conically shaped surfaces for centering.

5. Housing according to one of claims 1 to 4, characterized in that the base plate unit (11) and / or the housing cover (10) have interchangeable plug-in transducers and / or a transmitter-receiver unit (transceiver).

6. Housing according to claim 5, characterized in that the transducer or transducers are arranged on a plug-in card.

7. Housing according to one of claims 1 to 6, characterized in that one or more glass fibers as a fiber reserve on guides, brackets or protective channels in the edge region of the base plate unit are wound substantially circular.

8. Housing according to one of claims 1 to 7, characterized in that splices, optical plugs, splitters, taps and / or wavelength multiplexers are fastened to the inside of the base plate unit, preferably being releasably fastened via plug connections.