NL1026441C2 - Device for selectively coupling a number of first glass fibers with a number of second glass fibers. - Google Patents

Abstract

The device (1) for a fiber to the home system or a fiber to the office system selectively couples a number of first glass fibers (4) with a number of second glass fibers (5). It comprises a coupling panel (2) which on a first side is provided with a number of first connecting points (6) for the connection of the first glass fibers and is also provided with a number of second connecting points (7), corresponding to the first connecting points, for the connection of the second glass fibers. The coupling panel is provided with connector blocks (3) for connection of first glass fibers to second such fibers. On each connector block eight first and eight second glass fibers are connected. The first glass fibers conduct incoming signals from providers, such as telephone, cable and internet, whereby the second glass fibers are each connected with a user/subscriber. Each first class fiber is connected with a first connecting point by means of a plug (8). Each second glass fiber is connected with a second connecting point by means of a ferrule (9).

Description

Device for selectively coupling a number of first glass fibers with a number of second glass fibers! i | 5! FIELD OF THE INVENTION

The invention relates to a device for selectively coupling a number of first glass fibers with a number of second glass fibers. Such a device can for instance be applied in a so-called fiber-to-the-home system or a fiber-to-the-office system, or in a exchange where a separation must be made between "local loop" and the fixed network.

BACKGROUND OF THE INVENTION

With the growing use of the Internet, the increasing telephone traffic and IS developments such as "TV-on-demand" and HDTV, the need for broadband digital data communication has increased enormously. To meet this need, optical fiber optic networks are being laid at a rapid pace. Fiber optic technology is currently the most suitable for long-distance communication due to the large amount of data that can be transmitted over a fiber optic network at low losses and at high speed. WDM (wavelength division multiplexing) is used for transmitting a large number of signals in parallel over a single fiber optic.

It is customary to have the glass fibers with the incoming optical signals from one or more providers run to a node to which several users are connected by means of metal (coax) cables: the so-called fiber-to-the-node system. The optical signals are then converted at the location of the node into electrical signals which are subsequently transported to the end users by means of the metal cables, but this is at the expense of the transmission speed. That is why a system is now being developed in which glass fibers are also used between the node and end users. To this end, a number of incoming glass fibers must be connected to a number of outgoing glass fibers at the location of the node. This way, every end user can be connected to his own provider (s) or "backbone". Since the number and type of providers can change over time and each user can subscribe or cancel a subscription or subscriptions with a provider or providers at a given moment, changes to the connections must always be possible.

Furthermore, a very precise mutual positioning of the glass fibers 5 to be connected is necessary in order to achieve good low-loss optical couplings. For the singlemode optical glass fibers customary in optical communication networks, we then talk about tolerances in the order of micrometers and tenths of a degree.

There is therefore a need for a cost-effective, compact device with which the incoming glass fibers can be coupled quickly and relatively simply, selectively and releasably to a relatively large number of outgoing glass fibers. In addition, the glass fibers to be joined must be able to be positioned very precisely with respect to each other. All this within a space that is limited as much as possible, whereby the whole remains orderly and well-arranged and each individual connection sufficiently accessible. The object of the invention is to provide such a device.

Summary of the invention

To this end the invention provides a device for selectively coupling a number of first glass fibers with a number of second glass fibers, which device comprises a coupling panel, which coupling panel is provided on a first side with a number of first connection points for connecting the first glass fibers and is also provided of a j | number of second connection points corresponding to the first connection points for connecting the second glass fibers. Such a device can for instance be applied in a fiber-to-the-home system or fiber-to-the-office system, or in a central office, wherein the first glass fibers can be selectively connected to the second in an orderly and well-arranged manner. glass fibers.

In addition, the connection points may comprise spaces for receiving plugs. The glass fibers can thus be mutually coupled quickly and relatively simply, selectively and releasably. Furthermore, a very precise mutual positioning of glass fibers to be connected is possible and thus good low-loss optical couplings can be achieved.

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The connection points are preferably arranged in a number of rows offset relative to each other. As a result, the connection points are and remain more accessible, and the whole remains organized and organized.

The device preferably also comprises a number of support elements for positioning and retaining glass fibers, these support elements being placed in a stepped arrangement. Thanks to the stepped arrangement, the individual support elements are easily accessible and the whole remains well-organized and well-ordered, even with a large number of fibers and a high density of glass fibers. The support elements also serve as strain relief.

10

The device preferably also comprises a number of buffer elements for guiding and buffering portions of glass fibers. In this way excess lengths, for example needed for making welded connections, can be neatly concealed. A minimum bending radius of the glass fibers can also be ensured here.

15

Preferably, the buffer elements each have substantially a wheel shape, they are arranged next to each other in line and they are rotatable about an axis. By placing them in line next to each other a high density can be achieved, which benefits the compactness of the device. The shaft is preferably removable, so that more working space can be created (temporarily) during the connection of the glass fibers.

The device preferably also comprises at least one guiding element for guiding glass fibers. The guide element can be provided with curved guide channels or curved guide surfaces. Glass fibers can be guided and discharged by means of such a guiding element, whereby a minimum bending radius is guaranteed.

Brief description of the drawings

The invention is explained below with reference to a non-limiting exemplary embodiment of a device according to the invention. Herein shows: - FIG. la shows a side view of an exemplary embodiment of a device according to the invention; FIG. 1b a front view thereon, and 1026441 FIG. 1c a rear view thereon; FIG. 2a is a top view of a first exemplary embodiment of a guide element according to the invention, and - FIG. 2b a front view thereon; 5; FIG. 3a is a top view of a second exemplary embodiment of a guide element according to the invention, and - FIG. 3b a front view thereon.

Detailed description of the invention

FIG. 1 shows an exemplary embodiment of a device according to the invention (1). The device (1) comprises a coupling panel (2) provided with connecting blocks (3) for connecting a number of first glass fibers (4) to a number of second glass fibers (5). In this example, 8 first (4) and 8 second glass fibers (5) can be connected to each connector block (3). The first glass fibers (4), for example, guide the incoming signals from a number of providers, such as telephone, cable and Intemet providers, the second glass fibers (5) being each connected to a user / subscriber. Each first glass fiber (4) is connected to a first connection point (6), in this example by means of a plug (8). Each second glass fiber (5) is connected to a second connection point (7), in this example by means of a ferrule (9). In this way a precise alignment of the glass fibers to be connected is possible and thus a good optical coupling.

The connector blocks (3) in this example form two rows staggered relative to each other. The connection points (6, 7) thus remain more accessible through the connected groups of glass fibers (4, 5). In total there are 60 connector blocks (3) and 60x8 = 480 first and second connection points (6.7).

The second glass fibers (5) each lie within a protective envelope tube (10). These tubes (10) are inserted from below and clamped in support elements (11) which are placed in a stepped arrangement. Thus the tubes (10) are neatly arranged, whereby the support elements (11) also serve as strain relief. The stepped arrangement promotes the clarity and accessibility of the whole.

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In order to be able to weld the second glass fibers (5), additional length is required which must be concealed after welding. To that end, buffer elements (12) are provided around which the excess lengths of, in this example, 8 second glass fibers (5) are always wound. The buffer elements (12) are arranged next to each other in line and are rotatable about an axis (13). So

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5, a high density is obtained, and a maximum flexibility in winding up. The shaft (13) can thereby be removable in order to temporarily gain more working space when connecting, welding and winding up the glass fibers.

The device (1) also comprises guide elements (20, 30) for guiding the first 10 and second glass fibers (4, 5).

The first glass fibers (4) can be guided to a side of the device (1) by means of a first guide element (20). To this end, the first guide element (20) is provided with curved guide channels (21, 22), see Figs. 2. In this example there are guide channels (21) leading to one side of the device and guide channels 15 (22) leading to the other side of the device. In practice it will often be chosen to discharge the glass fibers (4) to a single side. A minimum bending radius is guaranteed by discharging the glass fibers (4) through the guide channels (21,22).

The second glass fibers (5) can be discharged along a second guide element (30). To this end, the second guide element (30) is provided with curved guide surfaces (31), see Figs. 3. By draining the glass fibers (5) along the guide surfaces (31), a minimum bending radius is again guaranteed.

One or more of such devices (1) can be placed in a housing and thus form, for example, a node in a fiber-to-the-home system or a fiber-to-the-home system, or be part of a central office. The incoming glass fibers can for instance also be connected to a first coupling panel, and the outgoing glass fibers to a second coupling panel, after which selective couplings can be made between the incoming and outgoing glass fibers by making connections between the coupling panels with one another by means of third glass fibers.

It will thus be clear to a person skilled in the art that the invention is not limited to the exemplary embodiment shown and described, but that several embodiments with different configurations and arrangements are possible within the scope of the invention.

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Claims (10)

Device (1) for selectively coupling a number of first glass fibers (4) with a number of second glass fibers (5), which device comprises a coupling panel (2), which coupling panel is provided on a first side with a number of first connection points (6) ) for connecting the first glass fibers and also being provided with a number of second connection points (7) corresponding to the first connection points for connecting the second glass fibers. Device as claimed in claim 1, wherein the connection points comprise spaces for receiving 10 plugs. Device as claimed in claim 1 or 2, wherein the connection points are arranged in a number of rows offset relative to each other. 4. Device as claimed in any of the claims 1-3, wherein the device also comprises a number of supporting elements (11) for positioning and retaining glass fibers, said supporting elements being placed in a stepped arrangement. Device according to any of claims 1-4, wherein the device also comprises a number of buffer elements (12) for guiding and buffering portions of glass fibers. Device as claimed in claim 5, wherein the buffer elements each have substantially a wheel shape, are arranged next to each other in line and are rotatable about an axis (13). Device as claimed in claim 6, wherein the shaft is removable. Device as claimed in any of the claims 1-7, wherein the device also comprises at least one guide element (20,30) for guiding glass fibers. Device according to claim 8, wherein the guide element (20) is provided with curved guide channels. Device according to claim 8, wherein the guide element (30) is provided with curved guide surfaces. 1026441