DE102018129234B4 - Collocation module, module assembly and fiber optic distribution device - Google Patents

Abstract

Collocation module (28; 30) for a distribution cabinet (24), comprising a housing (46) having a base (54; 62) and side walls, wherein the housing (46) has at least one connecting area (50) for placing and connecting the collocation module (28; 30) on the distribution cabinet (24),
wherein the base (54; 62) of the collocation module (28; 30) has at least one cable feedthrough (56, 58; 64) through which cables and/or pipes with optical fibers can be guided into the collocation module (28; 30), and
wherein the housing (46) of the collocation module (28; 30) has an access opening (48) to the surroundings of the collocation module and a lockable closure element (52) associated with the access opening (48).

Description

The invention relates to a collocation module for a distribution cabinet, a module assembly and a fiber optic distribution device.

Fiber optic networks for data transmission have multiple network levels. Main fiber optic cables with multiple fiber optic cables run from so-called main distribution frames to fiber optic network distributors, where the consumer is connected to the fiber optic network. In the fiber optic network distributors, the individual fiber optic cables of the main fiber optic cable are split up and connected to the customer's fiber optic and/or copper lines. In the case of copper lines, a corresponding converter is also inserted between them to convert optical signals into electrical signals.

Non-discriminatory access to the fiber optic network must be possible for multiple competing providers of communications services. In other words, co-location must be planned for during the construction of the fiber optic network, and access to the co-location site must be made possible for multiple providers on a non-discriminatory basis.

One option is to provide a separate fiber optic network distribution cabinet for each provider. Each provider then has a separate distribution cabinet to which it has exclusive access. However, these additional distribution cabinets involve additional costs and may require additional regulatory approval.

The CN 203 773 111 U discloses a multi-supplier distribution cabinet having a continuous housing enclosing the entire distribution cabinet, the interior of the distribution cabinet being divided into several functionally different sections.

The object of the invention is therefore to provide a fiber optic distribution device that enables simple and cost-effective collocation.

The object is achieved according to the invention by a collocation module for a distribution cabinet, in particular a cable distributor, comprising a housing having a base and side walls, wherein the housing has at least one connection area for placing and connecting the collocation module on the distribution cabinet. The base of the collocation module has at least one cable feedthrough through which cables and/or pipes with optical fibers can be guided into the collocation module. The housing of the collocation module has an access opening to the surroundings of the collocation module and a lockable closure element associated with the access opening.

With the collocation module according to the invention, the distribution cabinet containing the fiber optic technology of a first provider can be easily expanded. In particular, the collocation module houses the fiber optic technology of a second provider. This fiber optic technology can be connected through the cable feedthrough to the optical fibers, which allow the additional provider access to the fiber optic network at the location of the distribution cabinet. Furthermore, the fiber optic technology is easily accessible to the additional provider via the lockable access opening. The collocation module thus enables simple collocation at the location of the distribution cabinet without the need for additional distribution cabinets.

In particular, the access opening is provided on a side wall of the collocation module.

Preferably, the connection area is provided on the underside of the housing. Accordingly, the collocation module is placed on top of the distribution cabinet and attached to the distribution cabinet. Further preferably, the housing of the collocation module can be firmly connected to the distribution cabinet, for example, using screws, bolts, and/or other suitable fastening means.

In particular, the housing of the collocation module is open at its top, meaning the collocation module itself does not have its own roof or similar. For example, when mounting the collocation module on the distribution cabinet, one of the roofs of the distribution cabinet is removed, the collocation module is placed on the distribution cabinet, and the roof is then mounted on the collocation module.

Preferably, the closure element is a door, a flap, or a cover plate that completely closes the access opening. This ensures that only the respective provider has access to the fiber optic technology housed in the collocation module. A door is understood to be a closure element that opens or closes the access opening by pivoting about a substantially vertical axis. A flap, on the other hand, is understood to be a closure element that opens or closes the access opening by pivoting about a substantially horizontal axis. closes. If, however, the closure element is designed as a cover plate, this can be removed non-destructively to release the access opening, preferably only with the use of tools.

Preferably, the closure element has locking means by which the closure element can be locked. For example, a lockable lock is attached to the closure element. Alternatively, the closure element can be attached to the housing by means of screws that have a tool-specific tool engagement recess. Alternatively or additionally, the closure element can be sealed.

One aspect of the invention provides that the collocation module has a roof element, in particular wherein the roof element is pivotably mounted at an upper end of the housing. The roof element is thus a flap accessible from the outside, which is why the roof element is preferably lockable and/or permanently connectable to the housing. For example, the roof element can be locked together with the closure element. The roof element can be a roof of the distribution cabinet, as described above.

According to a further aspect of the invention, the collocation module comprises a fiber transfer device for connecting cables, in particular optical fibers, which is provided within the housing. In particular, individual fibers of main optical fiber cables are connected to customer-side optical fibers and/or copper lines in the fiber transfer device.

For example, an access cable and an outgoing cable are each routed to the fiber transfer device, with the access cable containing the customer-side fiber optic cables and/or copper wires, and the outgoing cable containing fiber optic cables from the main fiber optic cable. The individual fibers of the access cable and the outgoing cable can be spliced together in the fiber transfer device.

According to a further embodiment of the invention, the fiber transfer device comprises a cassette carrier module and optionally cassettes in the cassette carrier module, and/or the fiber transfer device comprises a cable surplus storage unit. The cassette carrier module enables particularly simple and clear fiber management, while the cable surplus storage unit enables the orderly storage of excess sections of fiber optic cables, in particular excess sections of the access cable and the outgoing cable.

The cassette carrier module is also referred to as an "organizer" or "splice assembly." These cassettes include so-called single and multi-fiber management cassettes (E&MMS cassettes), also known as splice cassettes. Within the cassettes, one or more individual fibers of the access cable can be spliced to one or more individual fibers of the outgoing cable.

Preferably, at least a portion of the fiber transfer device, in particular the cassette carrier module, is slidably attached to the housing, in particular wherein at least the portion of the fiber transfer device, in particular the cassette carrier module, is attached to the housing by means of two guide rails. The cassette carrier module can thus be slid out of the fiber transfer device, in particular like a drawer, preferably out of the housing. This facilitates assembly and maintenance work on the fiber transfer device. In particular, installation and/or replacement of cassettes accommodated in the cassette carrier module is facilitated.

At least a portion of the fiber transfer device, in particular the cable slack storage, can be pivotably mounted on the housing, in particular in a plane perpendicular to the access opening. The cable slack storage can preferably be pivoted out of the housing. This further simplifies assembly and maintenance work on the fiber transfer device, particularly during the assembly of the access cable and the outgoing cable.

Preferably, the excess cable storage is provided above the cassette carrier module.

The object is further achieved according to the invention by a module assembly with a first collocation module as described above and a second collocation module as described above, wherein the housing of the second collocation module is placed on the housing of the first collocation module and is firmly connected to the latter. The module assembly can then, just like the collocation module described above, be placed on a distribution cabinet and connected to the latter. In particular, the first collocation module contains the fiber optic technology of a second provider, while the second collocation module contains the fiber optic technology of a third provider. The module assembly according to the invention therefore enables collocation at the location of the distribution cabinet for at least three providers in a simple manner.

The module assembly can of course be expanded by adding further collocation modules big is expandable, so that collocation for more than three providers is also possible.

The two collocation modules can be designed differently from each other, but preferably have at least the same height. Alternatively, the two collocation modules can also be designed as identical parts.

One aspect of the invention provides that the first collocation module has at least one first cable feedthrough and at least one second cable feedthrough in the floor and comprises a cable duct within the housing, wherein the cable duct originates from the at least one second cable feedthrough in the floor and extends over the entire height of the first collocation module, wherein the at least one first cable feedthrough is provided outside the cable duct. Cables and/or pipes with optical fibers can be guided through the cable duct from the distribution cabinet through the first collocation module into the second collocation module, in particular an access cable and an outgoing cable. These cables and/or pipes therefore run within the first collocation module in a separate area that is not accessible from an interior of the first collocation module. This is particularly advantageous if, for example, one provider has exclusive access to the first collocation module and another provider has exclusive access to the second collocation module, whereby access to the fiber optic technology of the other provider is to be denied. This also avoids confusion as to which supplier the cables and/or pipes belong to.

In particular, the base of the second collocation module is plate-shaped, preferably a metal sheet. The cable feedthrough of the second collocation module is preferably designed as a recess in the base, in particular, the recess being provided at the edge of the base.

The bottom of the second collocation module can be configured to be substantially complementary to an opening on the top of the first collocation module, so that the bottom of the second collocation module forms a lid for the first collocation module. The bottom of the second collocation module thus separates the two collocation modules from each other.

Analogously, the base of the first collocation module can be designed in a plate-shaped manner, in particular as a metal sheet. The second cable feedthrough of the first collocation module is preferably designed as a recess in the base, in particular with the recess being provided at the edge of the base.

More preferably, the recesses in the floors of the first and second collocation modules are located vertically one above the other.

The object is further achieved according to the invention by a fiber optic distribution device comprising a distribution cabinet having a distribution housing, and at least one collocation module as described above or a module assembly as described above, wherein the collocation module or the module assembly is attached to the distribution housing. In particular, the distribution cabinet contains the fiber optic technology of a first provider, while the first collocation module contains the fiber optic technology of a second provider and/or the second collocation module contains the fiber optic technology of a third provider. The fiber optic distribution device according to the invention thus enables collocation at the location of the distribution cabinet for at least three providers in a simple manner.

The distribution cabinet is specifically designed for outdoor use. Together with the fiber optic technology housed within the cabinet, it forms a fiber optic network distributor, which is designed, for example, along the lines of the "KVz82" model.

Preferably, the distribution cabinet has a height that is greater than the respective height of the collocation modules, in particular at least twice as large, for example at least 3.5 times as large.

According to a further aspect of the invention, the distribution housing has at least one access opening and a lockable closure element, which is separate from the access opening of the collocation module or from the access openings of the module assembly. Thus, each provider has separate access to its fiber optic technology.

The closure element of the distributor housing preferably has locking means by which the closure element can be locked. For example, a lockable lock is attached to the closure element. Alternatively, the closure element can be attached to the housing by means of screws that have a tool-specific tool engagement recess. Alternatively or additionally, the closure element can be sealed.

According to one embodiment of the invention, the fiber optic distribution device has a front side, wherein at least two of the access openings In particular, all access openings are provided on the front. The access openings preferably have the same width.

Further preferably, the access openings each extend substantially across the entire width of the front side, in particular across at least 80% of the width of the front side, preferably across at least 90% of the width of the front side. This ensures optimal access to the fiber optic technology housed inside the fiber optic distribution device.

In particular, the distribution cabinet has a roof, wherein the roof is attached to the housing of the first collocation module or the second collocation module and closes the corresponding collocation module. The housing of the first and/or second collocation module is, for example, open at its top, i.e., the collocation module itself does not have its own roof, lid, or similar.

For example, when installing the corresponding collocation module(s) on the distribution cabinet, one roof of the distribution cabinet is first removed. Then, the collocation module(s) is/are attached to the distribution cabinet, and the roof of the distribution cabinet is mounted on the corresponding collocation module.

A further aspect of the invention provides that the collocation module or module assembly has the same footprint as the distribution cabinet and/or that the housing of the collocation module or collocation modules of the module assembly has the same cross-section as the distribution cabinet's distribution cabinet's housing. Thus, the distribution cabinet is only extended in height by the collocation module or module assembly, while, for example, the width and depth of the collocation module and module assembly correspond to the width and depth of the distribution cabinet, respectively.

In a further embodiment of the invention, the fiber optic distribution device has at least a first cable, wherein the first cable runs through the distribution cabinet and the cable feedthrough of the floor of the collocation module into the collocation module, in particular wherein the fiber optic distribution device has at least a second cable which runs through the distribution cabinet, through the second cable feedthrough of the floor of the first collocation module, through the cable duct of the first collocation module and through the cable feedthrough of the floor of the second collocation module into the second collocation module.

In particular, an access cable and an outgoing cable lead from the distribution cabinet into each of the collocation modules.

Within the scope of the invention, the terms “access cable” and “outgoing cable” are also intended to include cable bundles or corresponding cable-carrying pipes.

• - 1 schematisch ein Glasfasernetz mit einer erfindungsgemäßen Glasfaserverteilereinrichtung mit erfindungsgemäßen Kollokationsmodulen;
• - 2 in einer Schrägansicht eine erfindungsgemäße Glasfaserverteilereinrichtung gemäß einer ersten Ausführungsform mit einer erfindungsgemäßen Modulbaugruppe mit erfindungsgemäßen Kollokationsmodulen;
• - 3 die erfindungsgemäße Glasfaserverteilereinrichtung von 2 in einer Schnittansicht;
• - 4 in einer Schrägansicht eine erfindungsgemäße Glasfaserverteilereinrichtung gemäß einer zweiten Ausführungsform;
• - 5 in einer Schrägansicht eine erfindungsgemäße Modulbaugruppe;
• - 6 in einer um 90° gedrehten Schrägansicht die Modulbaugruppe von 5; und
• - 7 in einer Schrägansicht ein erfindungsgemäßes Kollokationsmodul.

Further advantages and features of the invention will become apparent from the following description and the accompanying drawings, to which reference is made. In these drawings:

• - 1 schematically shows a fiber optic network with a fiber optic distribution device according to the invention with collocation modules according to the invention;
• - 2 in an oblique view, a fiber optic distribution device according to the invention according to a first embodiment with a module assembly according to the invention with collocation modules according to the invention;
• - 3 the inventive fiber optic distribution device of 2 in a sectional view;
• - 4 in an oblique view a fiber optic distribution device according to the invention according to a second embodiment;
• - 5 in an oblique view a module assembly according to the invention;
• - 6 in a 90° angled view of the module assembly of 5 ; and
• - 7 in an oblique view a collocation module according to the invention.

In 1 A fiber optic network 10 is shown schematically, which comprises a main distribution frame 12 and a fiber optic distribution device 14, which is connected to the main distribution frame 12 via a main fiber optic cable 16. The main fiber optic cable 16 has a plurality of fiber optic cables 18, wherein one or more of the fiber optic cables 18 can be designed as an empty pipe.

In the fiber optic distribution device 14, the individual fibers of the fiber optic cables 18 of the main fiber optic cable 16 are split and connected to individual fibers of customer-side fiber optic cables and/or copper lines. In the case of copper lines, a corresponding converter is also interposed to convert optical signals into electrical signals. In the following, it is assumed, without limiting the generality, that these are customer-side fiber optic cables 20.

The customer-side fiber optic cables 20 lead to the individual fiber optic distribution devices tung 14 to the fiber optic network 10, which may have several usage units, for example several residential units.

Non-discriminatory access to the fiber optic network 10 must be possible for multiple competing providers of communications services. In other words, it must be possible for multiple providers to connect the buildings 22 to the fiber optic network 10. For this purpose, each customer-facing fiber optic cable 20 has at least three individual fibers to enable access for at least three different providers. Furthermore, a so-called collocation site is required, where the multiple providers are granted access to the fiber optic network 10.

This collocation site is formed by the fiber optic distribution device 14, which has a multi-part structure for this purpose. The basic structure and basic functionality are already known from 1 The fiber optic distribution device 14 comprises a distribution cabinet 24 and a module assembly 26, which has a first collocation module 28 and a second collocation module 30.

The distribution cabinet 24 contains the fiber optic technology of a first provider, while the first collocation module 28 contains the fiber optic technology of a second provider and the second collocation module 30 contains the fiber optic technology of a third provider.

The distribution cabinet 24 is, in particular, a distribution cabinet for outdoor use, as is known from the prior art. The distribution cabinet 24, together with fiber optic technology housed in the distribution cabinet 24, forms a fiber optic network distributor, which is designed, for example, in the "KVz82" style.

Both the fiber optic cables 18 of the main fiber optic cable 16 and the customer-side fiber optic cables 20 terminate in the distribution cabinet 24. In the distribution cabinet 24, the individual fibers of the fiber optic cables 18 and the individual fibers of the customer-side fiber optic cables 20 are split and reorganized according to their affiliation to the providers.

Those individual fibers belonging to the second provider are routed from the distribution cabinet 24 into the first collocation module 28, in particular bundled in the form of a first outgoing cable 32 and a first access cable 34.

The first access cable 34 contains the individual fibers of the customer-side fiber optic cable 20 relevant for the second provider, while the first outgoing cable 32 contains the individual fibers of the fiber optic cable 18 relevant for the second provider.

Those individual fibers belonging to the third provider are routed from the distribution cabinet 24 through the first collocation module 28 into the second collocation module 30, in particular bundled in the form of a second access cable 36 and a second outgoing cable 38.

The structure of the fiber optic distribution device 14 is described below using the 2 to 4 explained in more detail, which show the fiber optic distribution device 14 without the fiber optic technology installed therein.

The distribution cabinet 24 comprises a distribution housing 40 having an access opening 42 on its front side. Furthermore, the distribution cabinet 24 comprises a lockable closure element 44 associated with the access opening 42, which can selectively close or open the access opening 42.

The access opening 42 is provided on a front side of the distributor housing 40. The access opening 42 extends substantially over the entire width of the front side, in particular over at least 80% of the width of the front side, preferably over at least 90% of the width of the front side.

In the in the 2 to 4 In the embodiments shown, the closure element 44 is designed as a lockable door. Alternatively, however, the closure element 44 can also be designed as a flap or a cover plate.

Preferably, the closure element 44 has locking means by which the closure element 44 can be locked. For example, a lockable lock is attached to the closure element 44. Alternatively, the closure element 44 can be attached to the distributor housing 40 by means of screws having a tool-specific tool engagement recess. Alternatively or additionally, the closure element 44 can be sealed.

The first collocation module 28 and the second collocation module 30 each have a housing 46 having an access opening 48 on its front side and a connecting area 50 in the lower region of its side walls. Furthermore, the first collocation module 28 and the second collocation module 30 each have a lockable closure element 52, which is assigned to the respective access opening 48 and can selectively close or open it.

The access opening 42 of the distribution cabinet 24 and the respective access openings 48 of the two collocation modules 28, 30 are formed separately from each other. However, all access openings 42 and 48 can have the same width.

In the in the 2 to 4 In the embodiments shown, the closure elements 52 are each designed as a lockable flap. Alternatively, however, the closure elements 52 can also be designed as a door or a cover plate.

Preferably, the closure elements 52 each have locking means by which the closure elements 52 can be locked. For example, a lockable lock is attached to each closure element 52. Alternatively, the closure elements 52 can be attached to the housing 46 by means of screws having a tool-specific tool engagement recess. Alternatively or additionally, the closure elements 52 can be sealed.

The connection area 50 of the first collocation module 28 serves to firmly connect the first collocation module 28 to the distribution cabinet 24, in particular by means of suitable fastening means such as screws or bolts.

Analogously, the connection area 50 of the second collocation module 30 serves to firmly connect the second collocation module 30 to the first collocation module 28, in particular by means of suitable fastening means such as screws or bolts.

The fiber optic distribution device 14 is accordingly formed by the distribution cabinet 24, by the first collocation module 28 attached to the distribution cabinet 24 and by the second collocation module 30 attached to the first collocation module 28.

The collocation modules 28, 30 or the module assembly 26 have the same footprint as the distribution cabinet 24. Alternatively or additionally, the housing 46 of the collocation modules 28, 30 can have the same cross-section as the distribution housing 40 of the distribution cabinet 24.

In other words, the width and depth of the collocation modules 28, 30 or the module assembly 26 correspond to the width and depth of the distribution cabinet 24.

However, the distribution cabinet 24 has a height that is greater than the respective height of the collocation modules 28, 30, in particular at least twice as large, for example at least 3.5 times as large.

With regard to the above-mentioned components, the two collocation modules 28, 30 are essentially identical or at least very similar in structure. However, the two collocation modules 28, 30 differ in some aspects, which are explained below.

How particularly good in 3 As can be seen, the housing 46 of the first collocation module 28 has a plate-shaped base 54 which has at least one first cable feedthrough 56 and at least one second cable feedthrough 58 in its edge region.

Furthermore, the first collocation module 28 has a cable duct 60, which is delimited by a partition plate 61 and extends over the entire height of the first collocation module 28. The cable duct 60 is therefore a separate area in the first collocation module 28 that is not accessible from the interior of the first collocation module 28.

The at least one first cable feedthrough 56 opens into the first collocation module 28 in a region of the floor 54 that lies outside the cable duct 60, while the at least one second cable feedthrough 58 opens into the cable duct 60. The second cable feedthrough 58 is therefore provided in a region of the floor 54 in which the cable duct 60 is also located.

The second collocation module 30 has a plate-shaped base 62 that separates the two collocation modules 28, 30 from each other. However, the base 62 of the second collocation module 30 has only one cable feedthrough 64, which is designed in particular as a through-opening in the base 62.

The cable feedthrough 64 leads from the second collocation module 30 into the cable duct 60 of the first collocation module 28.

Accordingly, fiber optic cables and/or pipes can be routed from the distribution cabinet 24 into the first collocation module 28 through the at least one first cable feedthrough 56. In particular, the first access cable 34 and the first outgoing cable 32 are routed from the distribution cabinet 24 through the at least one first cable feedthrough 56 into the first collocation module 28.

In addition, the second access cable 36 and the second outgoing cable 38 can be guided through the at least one second cable feedthrough 58 in the floor 54 of the first collocation module 28, then through the cable duct 60 and then through the cable bushing 64 in the floor 62 of the second collocation module 30 into the second collocation module 30. Thus, the second access cable 36 and the second outgoing cable 38 are routed from the distribution cabinet 24 into the second collocation module 30 in such a way that no access to the second access or outgoing cable 36, 38 is possible from the first collocation module 28.

In contrast to the first collocation module 28, the second collocation module 30 also has a roof element 66 which is pivotally attached to an upper end of the housing 46 and which closes the second collocation module 30 at the top.

The roof element 66 is therefore a flap accessible from the outside, which is why the roof element 66 is preferably lockable and/or can be firmly connected to the housing 46 of the second collocation module 30.

The roof element 66 may be a roof of the distribution cabinet 24, but it may have been removed from the distribution cabinet 24 and mounted on the second collocation module 30.

For example, when mounting the collocation modules 28, 30 on the possibly already existing distribution cabinet 24, the roof element 66 is first removed from the distribution cabinet 24. Then, the collocation modules 28, 30 are attached to the distribution cabinet 24, and the roof element 66 is mounted on the second collocation module 30.

In an alternative embodiment described in 4 However, as shown, only one of the two collocation modules 28, 30 can be attached to the distribution cabinet 24. This is shown in 4 for example, the first collocation module 28. In this case, the roof element 66 can also be attached to the first collocation module 28. Furthermore, a cable duct 60 can be omitted.

All previous explanations essentially concern only the structure of the basic framework of the fiber optic distribution device 14 and not the fiber optic technology used in the fiber optic distribution device 14.

In 5 and 6 The module assembly 26 is shown with fiber optic technology installed therein. More specifically, a fiber transfer device 68 is provided inside each of the first collocation module 28 and the second collocation module 30. The fiber transfer device 68 includes a cassette carrier module 70 with a plurality of cassettes 72 and a cable overlength storage device 74 mounted above the cassette carrier module 70.

The cassette carrier module 70 is also referred to as an "organizer" or "splice assembly." The cassettes 72 are so-called single and multi-fiber management (E&MMS) cassettes, also referred to as splice cassettes.

Within each collocation module 28, 30, the corresponding access cable 34 or 36 and the corresponding outgoing cable 32 or 38 are connected to the fiber transfer device 68, wherein the cable excess length storage 74 receives excess sections of the access cable 34 or 36 and the outgoing cable 32 or 38.

In particular, the excess cable storage 74 has guide means 76 for guiding the access cable 34 or 36 and the outgoing cable 32 or 38. The guide means 76 are designed, for example, as eyelets.

The individual fibers of the access cable 34 or 36 and the outgoing cable 32 or 38 are connected to the cassette carrier module 70, wherein within the cassettes 72 one or more individual fibers of the corresponding access cable 34, 36 are spliced to one or more individual fibers of the corresponding outgoing cable 32, 38.

6 shows a variant of the fiber transfer device 68, according to which the excess cable storage 74 is pivotable about a vertical axis out of the housing 46, wherein the closure element 52 of the first collocation module 28 is not shown for reasons of clarity. In particular, the excess cable storage 74 is pivotable in a plane that extends perpendicular to the access opening 48.

In 7 A detailed view of the second collocation module 30 is shown. Alternatively or in addition to the pivotable attachment of the excess cable storage 74, the cassette carrier module 70 is slidably attached to the housing 46.

Even if only the cassette carrier module 70 of the second collocation module 30 is shown here, the cassette carrier module 70 of the first collocation module 28 can of course also be designed accordingly.

More specifically, the cassette carrier module 70 is attached to two guide rails 78 and can be moved out of and into the housing 46 like a drawer.

Of course, constructions with more than two collocation modules 28, 30 are conceivable.

Claims (16)

A collocation module (28; 30) for a distribution cabinet (24), comprising a housing (46) having a base (54; 62) and side walls, wherein the housing (46) has at least one connection area (50) for placing and connecting the collocation module (28; 30) on the distribution cabinet (24), wherein the base (54; 62) of the collocation module (28; 30) has at least one cable feedthrough (56, 58; 64) through which cables and/or pipes with optical fibers can be guided into the collocation module (28; 30), and wherein the housing (46) of the collocation module (28; 30) has an access opening (48) to the surroundings of the collocation module and a lockable closure element (52) associated with the access opening (48). Collocation module (28; 30) according to Claim 1 , characterized in that the closure element (52) is a door, a flap or a cover plate which completely closes the access opening (48). Collocation module (28; 30) according to Claim 1 or 2 , characterized in that the collocation module (28; 30) has a roof element (66). Collocation module (28; 30) according to one of the preceding claims, characterized in that the collocation module (28; 30) has a fiber transfer device (68) for connecting cables, which is provided within the housing (46). Collocation module (28; 30) according to Claim 4 , characterized in that the fiber transfer device (68) has a cassette carrier module (70) and/or that the fiber transfer device (68) has a cable excess length storage device (74). Collocation module (28; 30) according to Claim 4 or 5 , characterized in that at least a part of the fiber transfer device (68) is slidably attached to the housing (46). Collocation module (28; 30) according to one of the Claims 4 until 6 , characterized in that at least a part of the fiber transfer device (68) is pivotally attached to the housing (46). Module assembly (26) with a first collocation module (28) according to one of the preceding claims and a second collocation module (30) according to one of the preceding claims, wherein the housing (46) of the second collocation module (30) is placed on the housing (46) of the first collocation module (28) and is firmly connected thereto. Module assembly (26) according to Claim 8 , characterized in that the first collocation module (28) has at least one first cable feedthrough (56) and at least one second cable feedthrough (58) in the base (54) and comprises a cable duct (60) within the housing (46), wherein the cable duct (60) starts from the at least one second cable feedthrough (58) of the base (54) and extends over the entire height of the first collocation module (28), wherein the at least one first cable feedthrough (56) is provided outside the cable duct (60). Module assembly (26) according to Claim 8 or 9 , characterized in that the bottom (62) of the second collocation module (30) is plate-shaped. Fiber optic distribution device (14) with a distribution cabinet (24) having a distribution housing (40), and at least one collocation module (28; 30) according to one of the Claims 1 until 7 or a module assembly (26) according to one of the Claims 8 until 10 , wherein the collocation module (28; 30) or the module assembly (26) is mounted on the distributor housing (40). Fiber optic distribution device (14) according to Claim 11 , characterized in that the distributor housing (40) has at least one access opening (42) and a lockable closure element (44) which is separated from the access opening (48) of the collocation module (28; 30) or from the access openings (48) of the module assembly (26). Fiber optic distribution device (14) according to Claim 12 , characterized in that the fiber optic distribution device (14) has a front side, wherein at least two of the access openings (42, 48) are provided on the front side. Fiber optic distribution device (14) according to one of the Claims 11 until 13 , characterized in that the distribution cabinet (24) has a roof, wherein the roof is attached to the housing (46) of the first collocation module (28) or the second collocation module (30) and closes the corresponding collocation module (28; 30). Fiber optic distribution device (14) according to one of the Claims 11 until 14 , characterized in that the collocation module (28; 30) or the module assembly (26) has the same base area as the distribution cabinet (24) and/or that the housing (46) of the collocation module (28; 30) or the collocation modules (28, 30) of the module assembly (26) has the same cross-section as the distributor housing (40) of the distribution cabinet (24). Fiber optic distribution device (14) according to one of the Claims 11 until 15 , characterized in that the fiber optic distribution device (14) has at least a first cable (32, 34), wherein the first cable (32, 34) runs through the distribution cabinet (24) and the cable feedthrough (56) of the floor (54) of the collocation module (28; 30) into the collocation module (28; 30).

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