DE202021106964U1 - Coupling for blow-in connector - Google Patents

Abstract

Coupling (8) for connecting optical fibers, at least two blow-in plugs (20) being insertable into the coupling (8) to form a plug-in connection of the optical fiber connections, and the blow-in plugs (20) having at least one plug-in contact (1), by means of which an optical fiber cable (2nd ) is pre-assembled at the factory and the plug contact (1) has a ferrule holder (4) in which a ferrule (5) for accommodating the optical fibers of the optical fiber cable (2) is held, with the blow-in plug (20) having a lock receiving the optical fiber cable (2). (12a) for connecting the plug contact (1) to the coupling (8) and an anti-twist device between the lock (12a) and the coupling (8) in the final assembled state of the plug (20) through the plug connection in the longitudinal direction of the fiber optic cable (2) is formed between the lock (12a) and the clutch (8), so that the position of the fiber optic cable (2) in endmonti correct condition of the blow-in plug (20) in the coupling (8).

Description

The invention relates to a coupling for a blow-in connector according to the preamble of claim 1.

In optical fiber technology, optical fibers serve as a transmission medium for line-based telecommunications processes. Fiber optic cables are used, among other things, to connect buildings to telecommunications systems. For this purpose, the fiber optic cables are laid from distributors to the individual buildings. Empty pipes with a relatively small diameter are usually laid between the distributor and the respective building connection. The fiber optic cables can be pushed or blown through these empty tubes.

Connectors are mounted on the end of the fiber optic cable, which connectors usually have a standardized outer housing in order to be compatible with sockets or couplings of the connecting devices in the building into which the connector is inserted. However, the standardized outer housing is relatively bulky, so that the plugs are not suitable for being guided through the small dimensions of the empty conduits that have been laid.

Such plugs are, inter alia, from the U.S. 7,104,702 B2 , US 6,550,979 B1 , US 6,387,018 B1 and DE 10 2007 033 246 A1 famous.

These plugs are usually assembled by pushing or “blowing” the fiber optic cable through the empty conduit until the free end of the fiber optic cable protrudes from the conduit. The plug is then fitted on site to the free end of the fiber optic cable in order to be able to connect the building's communication system to it.

Since the end of the fiber optic cable has to be processed very precisely, the assembly of the plug has hitherto been relatively complex and has to be carried out by a suitably trained fitter. The fitter needs special tools and devices for this. In the course of this work, the attenuation resistance of the fiber optic cable must also be checked on site, for which the fitter also needs the appropriate measuring devices. Due to this work to be performed on site, the costs incurred by the customer for the fiber optic connection are relatively high.

From the DE 103 42 908 A1 a connector for a plug connection of fiber optic connections with a plug contact is known, through which the fiber optic cable can be preconditioned at the factory. The work previously to be carried out on site by a fitter to connect the fiber optic cable can thus be carried out in advance in the factory with the known connector. Due to its small dimensions, the plug contact can be pulled or "blown" through the empty conduit. Only the outer housing of the plug together with a sealing cap needs to be mounted on the plug contact on site.

The preconditioned plug contact usually includes a ferrule with a ferrule flange. The fiber optic cable is connected to the ferrule. With a plug connection of glass fiber or fiber optic cables, the ends to be connected touch on the end faces of the ferrules. The assembly of the core cable with a ferrule requires a high level of precision. The core cable is therefore preferably pre-assembled with the ferrule. To lay the core cable, the ferrule can be protected by a suitable device, such as a cap.

the EP 1 450 187 relates to an optical connector with a spring-loaded connector pin. This is arranged on a pin holder that can be pushed into the connector housing from the rear. However, the spring element is assigned to the pin holder and is protected by an outer sleeve. This complicates the pre-assembly and increases the outer diameter of the pin holder.

Also the EP 2 115 509 A1 relates to connector parts for an optical connector.

In addition, methods for installing fiber optic networks using so-called blow-in techniques have recently become more important. By blowing fiber optic cables into existing, previously laid tube systems, it is possible to bring fiber optic cables to a desired location in a simple manner, for example for the "Fiber to the Home" (FTTH) application area.

A blow-in method and a device for blowing in fiber optic cables are, for example, from U.S. 6,572,081 B2 famous. The fiber optic cables described there have special guide devices at their ends that can withstand the mechanical loads during the blowing-in process. After reaching the end position at the end customer, the cables are equipped with plug parts for optical plug connections. For this purpose, for example, factory-assembled pigtails are attached to the bare fibers using splicing processes attached to the fiber optic cable, with space-consuming protective grommets also having to be installed.

Also from the U.S. 2008/0317410 A1 a method is known in which the cables with pre-assembled connector components (ferrule) are pressed by means of compressed air through empty pipes with a sufficiently large diameter to the receiving location.

So-called splice cassettes are known for splicing and connecting fiber optic lines in a distribution cabinet. Usually, such splice cassettes have a so-called crimp splice protection tray, which has a plate with two rows of compartments opposite one another, in which the ends of optical fibers to be connected, arriving from both sides, are inserted, which are connected to one another by V-shaped metal clips will. In the middle between the two rows of compartments there is a corresponding number of ridges into which the V-shaped clips, which are provided with a protective material for the glass fibers, are inserted. Up to twelve glass fibers are usually spliced and stored using these crimp splice protection trays. The crimp splice protection tray is usually snapped onto the base plate of the splice cassette.

Splice trays are generally housed in a fiber optic distribution frame having a plurality of stacked compartments or panels, each containing a larger number of trays.

From the EP 3 258 302 A1 such a splice cassette for splicing and connecting optical fibers in a distribution cabinet is known.

The splice cassettes can be accommodated in so-called splice boxes, which represent the "end" of a fiber optic cable route in which the individual fiber optic cables or fiber optic cables are fanned out. Central components of a splice box are the splice cassettes mentioned above, which accommodate the fiber optic cables and their reserve, as well as a patch panel, on which there are different connectors, to which patch cables can then be plugged in to forward the signals.

So-called leaf cassettes, which allow several splices to be stored on the various leaves in a splice box, can be provided as highly occupied splice cassettes. The cassettes can be used for all fiber types. 8 to 12 fibers can be accommodated in the mostly telecom standardized versions.

Such a fiber optic splice box with at least one flexibly connected connector is from DE 20 2014 102 537 A1 famous.

Proceeding from this, the invention is based on the object of proposing a coupling for at least one blow-in connector for a plug-in connection of optical fiber connections, which can be produced easily and is characterized by simple assembly. Furthermore, the coupling should be inexpensive and thus be suitable, for example, for the "Fiber to the Home" (FTTH) application area.

To solve the problem, a coupling for inserting and connecting a plurality of blow-in connectors with the features of claim 1 is proposed. Advantageous configurations of the invention result from the dependent claims, the following description and the figures.

The invention relates to a coupling for connecting optical waveguides, in which case at least two blow-in plugs can be inserted into the coupling to form a plug-in connection of the optical waveguide connections.

According to the invention, the blow-in plugs have at least one plug-in contact, by means of which an optical fiber cable is pre-assembled at the factory. As a result, a building can be connected to a telecommunications network by means of fiber optic cables with little installation effort on site in the building. Because the assembly or pre-assembly of the fiber optic cable end using the plug contact means that the fiber optic cable end can be processed and the damping resistance at the fiber optic cable end can be checked at the factory. It is also possible, for example, to grind the end face of the fiber optic cable end and to prepare corresponding quality reports at the factory, so that such activities that were previously carried out on site are no longer necessary. The compact dimensions of a plug-in contact also allow it to be laid, for example by blowing it through empty pipes with the smallest pipe diameter.

The plug contact has a ferrule holder in which a ferrule for receiving the optical waveguides of the optical waveguide cable is held. A ferrule holder is to be understood within the meaning of the invention as a component which holds the so-called ferrule. The ferrule is a guide element, preferably a small guide tube, which accommodates the optical waveguides of the optical waveguide cable. The ferrule can be made of ceramic, plastic, glass or metal, for example. It makes sense indicates that the ferrule is held securely in the ferrule holder. Due to the plug-in contact, the fiber optic cable in the preassembled state is already prepared for the subsequent installation state with regard to its fiber optic cable and is protected against external influences.

According to the invention, the blow-in plugs have a lock that accommodates the fiber optic cable, also called an adapter or sealing cap, for connecting the plug contact to the coupling. This makes it easy to connect to standardized sockets or couplings in the communication systems, particularly in the case of building connections. For example, the blow-in connector can easily be made into a standard LC connector by mating with the standard body part. As a result, the housing part can also be exchanged for another housing part, for example with a different connection standard, in a simple manner.

Furthermore, according to the invention, an anti-twist device is formed between the lock and the coupling in the final assembled state of the plug by the plug connection in the longitudinal direction of the optical fiber cable between the locking and coupling, so that the position of the optical fiber cable is secured in the final assembled state of the blow-in plug in the coupling.

The anti-twist protection of the blow-in connector is designed in such a way that only a single positive connection can be established between the connector and the coupling, i.e. there is only one end position, so that even pre-assembled light guides with beveled ferrule end faces (APC, "Angled Physical Contact") can be clearly aligned (in only one position!) can connect to each other.

According to the invention, the connector is designed as a blow-in connector, i.e. optical fibers with blow-in connectors are pushed and/or blown through the cable guide to the destination using compressed air.

Provision can be made for the locking mechanism to be mountable on the plug contact, in particular a ferrule holder of the plug contact, from the free end thereof. This ensures that after the fiber optic cable has been laid with the plug contact preconditioned on it through the empty pipe, the lock can be mounted from behind on the plug contact protruding from the empty pipe.

The blow-in connector is usually installed by pushing or blowing the fiber optic cable through the empty tube until the free end of the fiber optic cable protrudes from the tube. The blow-in connector is then mounted on site at the free end of the fiber optic cable in order to be able to connect the building's communication system to it.

The plug contact, in particular the ferrule holder of the plug contact, can be positively secured against axial displacement relative to the lock, in that at least one section that is raised or protruding relative to the inner circumference of the lock engages in a portion that is recessed relative to the outer circumference of the plug contact. The at least one raised section can be arranged on the locking mechanism and the at least one recessed section corresponding thereto can be arranged on the plug contact, in particular the ferrule holder. Of course, the reverse arrangement is also conceivable, according to which the at least one raised section is arranged on the plug contact and the at least one recessed section is arranged on the locking mechanism. It is also conceivable that several sections are provided, of which at least one raised section and at least one recessed section are arranged on the locking device and the sections corresponding thereto are arranged in a corresponding manner on the plug contact.

By engaging the raised section in the recessed section, a form-fitting connection between the locking device and the plug contact is realized in a particularly simple manner, by which the plug contact is secured in its axial position relative to the locking device. It is of course conceivable that the side walls of the recessed section are at a certain distance from the corresponding side walls of the raised section, so that, to a certain limited extent, the plug contact can be displaced axially relative to the locking between the side walls of the deep section is possible.

The raised section and the corresponding recessed section should preferably be designed to form the form-fitting anti-rotation lock between the lock and the plug contact, for example by the anti-rotation lock being formed by the outer peripheral surface or inner peripheral surface of the raised section and the indented section.

This can be implemented in a particularly simple manner if the plug contact has a plurality of recessed sections or raised sections distributed over its outer circumference, for example by the outer circumference of the plug contact being extended over a predetermined axial area is polygonal and the locking mechanism has a corresponding inner periphery designed as a polygonal profile, with the adjoining outer periphery or inner periphery being round or circular at the same time. The polygonal profile can be designed, for example, in cross section in the manner of a square, hexagon or polygon. An elliptical profile is also conceivable.

According to a first advantageous development of the coupling according to the invention, the plug-in connection between the lock and the coupling is formed by a lug or similar projection of the lock and by a complementary opening in the coupling; in particular, the coupling has two lugs or similar projections and the lock formed with two complementary openings.

This results in the plug-in connection when the coupling is pushed onto the locking mechanism, as a result of which the projection arranged on the locking mechanism snaps into the corresponding opening.

With this plug-in connection, a stable and durable safeguard against twisting and/or against axial displacement can be implemented. The arrangement of lugs or projections and the openings corresponding thereto is preferably selected in such a way that undercuts are avoided, so that the parts can be produced inexpensively, for example as injection molded parts. The locking device is particularly easy to produce if, according to one embodiment of the invention, it is made of plastic, in particular if it is formed by means of injection molding processes, extrusion processes or extrusion processes.

A further advantageous embodiment provides that the plug-in connection between the lock and the coupling is designed in the manner of a bayonet connection, the lock being fixed in the openings by means of the lugs or similar projections in the manner of the bayonet catch by a rotary movement relative to the coupling. This ensures a secure connection between the lock and the coupling in a simple manner. If necessary, a bayonet connection could also be released again. This property is particularly advantageous if (a) the measurement of the attenuation resistance after assembly of the connectors shows that the attenuation resistance is too high and the fiber optic surfaces therefore need to be cleaned, or (b) if the fiber optic cables have been incorrectly plugged in and the pairings have to be corrected later.

In a further variant of the invention, the plug contact on the coupling in the final assembled state of the plug is positively secured against twisting and for unambiguous positioning of the plug contact in the coupling by corresponding wall sections of the coupling and plug contact that are non-circular in cross section, with at least one section of the inner circumference of the Coupling with a corresponding portion of the outer circumference of the plug contact, in particular the ferrule holder of the plug contact, cooperates.

This enables a stable and durable anti-twist device and, moreover, a one-to-one positioning in a simple manner, in particular with cross-sections that are geometrically easy to implement. Non-circular cross sections are to be understood as meaning geometric cross-sectional shapes that deviate from a circular cross-sectional shape.

For example, an elliptical cross section or a square, in particular polygonal, cross section, for example in the form of a square, hexagonal or multi-cornered component, is conceivable as a non-circular cross section.

A non-rotatable connection of the locking mechanism with respect to the coupling can be implemented by a polygonal peripheral contour on the locking mechanism, with the coupling being able to have an inner peripheral contour that corresponds to this polygonal peripheral contour.

Securing against displacement in the axial direction can also be implemented in that the multi-edged peripheral contour is recessed or offset in relation to the outer peripheral surface of the locking mechanism at least over sections of the outer periphery. These sections serve as a stop for the corresponding inner peripheral contour of the clutch in the axial direction. Locking of the locking mechanism and coupling is thus also realized in the axial direction.

According to a further advantageous embodiment of the invention, it is provided that the section of the inner circumference of the coupling is designed as a flattening along the inner surface of the coupling and the section of the plug contact, in particular of the ferrule holder, is designed as a corresponding flattening along the lateral surface of the plug contact for an anti-twist device, so that the Fiber optic cable is secured against rotation in the final assembled state in a predetermined position in the coupling.

In this way, only a single positive connection can be established between plug and coupling, ie there is only one end position, so that even pre-assembled light guides with beveled ferrule end surfaces (APC, "Angled Physical Contact") can be connected to one another in a clearly aligned manner, for example in just one position. In this way, a unique positioning is obtained.

In a particularly advantageous manner, the coupling is formed from two housing parts, in particular structurally identical, the housing parts being connectable to one another by means of a snap-in connection and each housing part having at least one snap-in lug and at least one complementary snap-in eye. In this way, the advantages in the production and use of identical parts can be achieved if the two housing parts are designed as identical components. The latching connection can be detachable, but does not have to be. Snap-in connections enable precise, safe and direct connection of components.

In a further development of the invention, in the final assembled state of the plug in the coupling, a compression spring pre-assembled on the blow-in plug is prestressed and the position of the ferrule and the blow-in plug can be secured in the coupling by the compression spring.

The preconditioned plug contact can have the ferrule, a ferrule flange and the compression spring, which is preferably preassembled on the core cable. Due to the compression spring, the plug contact can be displaced to a certain extent in the axial direction against the pressure of the spring in relation to the unit made up of the coupling and the locking device. For this purpose, the spring is supported with its one end against the ferrule flange and with its other end against the lock. Furthermore, the plug-in contact on the locking mechanism is secured against twisting. For this purpose, one end face of the ferrule flange is designed as a multi-edged, conical peripheral surface, which comes into the operative position against a corresponding surface of the locking mechanism under prestressing of the compression spring. The compression spring ensures that the faces of the input and output connectors are held together with a defined pressure, which ensures minimal optical damping of the connector.

In particular, it can be provided that the plug contact on the lock is held against axial displacement relative to the lock, in particular against the force of the compression spring, the end of the lock facing the plug contact having a smaller inner diameter than the diameter of the compression spring.

It is conceivable that the ferrule has a polished section at its free end. In particular, it can be provided that the surface of the free end is inclined relative to the longitudinal axis of the fiber optic cable. For example, the angle of inclination can be between 6° and 12°, in particular 8°. With a slanted bevel, the light signal reflected back at the slanted coupling point is coupled out of the fiber optic cable, which leads to a higher return loss, also known as "return loss". This is particularly helpful with very high light transmission data rates, since the backscattered light is minimized at the transition point, which can negatively affect the light emission performance of the transmission element (e.g. laser).

According to an advantageous variant of the invention, the housing parts have a centering aid for the assembly of the coupling, the centering aid being formed by at least one pin protruding from the surface of one housing part, which engages in a complementary opening on the second housing part when the housing parts are connected to one another. in particular that both housing parts have at least one pin and a complementary opening. This configuration also means that the manufacturing costs of the clutch can be reduced, since identical parts are manufactured.

One embodiment of the invention provides that each housing part has at least one insertion opening for inserting the connector, the insertion openings of the fiber optic cables to be connected being opposite one another in the final assembled state of the coupling and the shape of the insertion openings ensuring that the connector is held securely in the insertion opening the outer contour of the plug is adapted.

One variant of the invention is particularly advantageous, in which the coupling has a preferably slotted sleeve, in particular a ceramic sleeve, for centering the ferrules for each connection of the fiber optic cables, with the sleeve being inserted in the housing parts of the coupling in such a way that it holds the ferrules of the surrounds the blow-in connector to be connected and is centered in the final assembled state.

It is advantageous that the outer shape of the coupling is designed in such a way that the coupling can be inserted into an optical fiber splice cassette.

The coupling can advantageously be made of plastic, for example polybutylene terephthalate (PBT).

Another idea of the invention relates to a system for connecting fiber optic cables with a coupling and as described above preferably with a blow-in connector as described above.

According to an advantageous embodiment of the system, it is provided that the blow-in connector for a plug-in connection of optical fiber connections has at least one plug contact, by means of which the optical fiber cable is pre-assembled at the factory, the plug contact having a ferrule holder in which a ferrule for receiving the optical fibers of the optical fiber cable is held, wherein the plug has a locking mechanism that accommodates the fiber optic cable for connecting the plug contact to a coupling or to a housing part, in particular a standardized housing part, for the plug to be connected to a socket or similar receiving part, the locking mechanism engaging the plug contact from its free end is mountable and wherein an anti-twist device between the lock and the coupling or the housing part in the final assembled state of the plug by a plug connection between the lock and the coupling or housing part il is formed.

According to a further embodiment of the system, the clutch, in particular a housing part of the clutch, can be connected to a housing part of a further clutch, in particular a standard LC clutch. The LC connector, also called lucent connector or standard LC connector, is one of the most common fiber optic connector types.

With this connection of the two housing parts of both clutches, preferably at least one latching lug of the further clutch can engage in a latching eye of the clutch and/or at least one latching lug of the clutch can engage in a latching eye of the further clutch.

The system for connecting fiber optic cables relates to a hybrid version of the coupling described above, preferably for connecting a blow-in connector as described above and a standard connector such as an LC connector.

This so-called hybrid coupling consists on one side of a connection for the blow-in connector described above and on the other side of a connection for a standard connector, such as an LC connector.

This has the advantage that all dimensions on the input side remain unchanged compared to a standard coupling, and the blow-in connector according to the invention can be mounted on the output side.

Furthermore, because of the geometrically smaller dimensions compared to a standard LC plug connection, consisting of 2x LC plugs and an LC coupling, and the omission of the kinked grommet on the blow-in plug side, the possible use in confined spaces is an advantage.

This hybrid version according to the invention can be used particularly advantageously in optical networks in which the hybrid version terminates the network on one side and a standard fiber optic cable is used on the other side to connect devices.

This applies, for example, to connections between fiber optics and subscriber connection sockets (TA), fiber optics and floor distributors (EV), fiber optics and building distributors (GV) or also with device connection boxes or subracks for installing fiber optic cable splitters and couplings.

Furthermore, the configuration according to the invention of the blow-in connector with the hybrid coupling has advantages with regard to negative environmental influences compared to a standard configuration, e.g. B. an LC connector on. Since the configuration according to the invention does not require a housing or a buckling grommet, the amount of material used per port/fiber is reduced by approximately 1 gram of polymer material. With a quantity of 10 million connections, this corresponds to a material saving of 10 t of polymer material. Added to this is the saving of energy for production, transport and disposal. The system according to the invention can therefore certainly be described as an environmentally friendly or "green product".

According to a further idea of the invention, an optical waveguide splice cassette is provided for connecting optical waveguide cables with a coupling as described above for receiving a plurality of blow-in plugs as described above for a plug-in connection of the optical waveguide connections.

At least one optical fiber splice cassette can be accommodated in an optical fiber splice box.

In a method for laying fiber optic cables, the ends of at least two fiber optic cables to be connected to one another can be laid at a slot, in particular by a blow-in method through a tube system to the slot, and the ends each have a previously described blow-in plug for the plug-in connection and the blow-in plugs are positioned in a previously described coupling by means of a lock and secured against twisting.

In telecommunications, for example, "Fiber to the Home" (abbreviated: "FTTH") refers to the laying of fiber optic cables into the home of an end consumer. Of course, the method is also suitable for other areas of application, which are known, for example, by the abbreviations FTTL, FTTC, FTTN or FTTB.

The fiber optic cable can be pre-assembled with a ferrule.

When connecting the blow-in connector to the coupling, a compression spring pre-assembled on a ferrule holder for holding the ferrule can be prestressed, with the position of the ferrule and the optical fiber cable in the coupling being able to be secured by the compression spring.

The blow-in plug can be connected to the coupling via a plug-in connection by means of a lock.

It is conceivable that the blow-in connector can be plugged into the housing part with a dust protection cap attached to the ferrule. As a result, in contrast to the prior art, the connector can be mounted with a lock on the housing part without having to remove the dust protection cap on the ferrule after blowing in. This prevents additional contamination of the connector end face until the final mating process.

The latch can be formed with a slot and snapped onto the fiber optic cable, and the latch can be mated with the coupler along the length of the fiber optic cable.

Further goals, advantages, features and application possibilities of the present invention result from the following description of an exemplary embodiment with reference to the drawing. All the features described and/or illustrated form the subject matter of the present invention, either alone or in any meaningful combination, even independently of their summary in the claims or their back-reference.

• 1 eine perspektivische Explosionsdarstellung einer erfindungsgemäßen Kupplung zum Verbinden von Einblassteckern,
• 2 ein Gehäuseteil der Kupplung gemäß 1 in einer Front- und einer Draufsicht,
• 3 den Einblasstecker mit Lichtwellenleiter in einer a) perspektivischen Explosionsdarstellung und b) zusammengesetzter Ansicht,
• 4 eine Spleißkassette zum Aufnehmen der Kupplung gemäß 1,
• 5 ein Gehäuseteil zum Aufnehmen des Einblassteckers,
• 6 das Gehäuseteil gemäß 5 in weiteren Ansichten,
• 7 eine weiteres System einer Verbindung zwischen der erfindungsgemäßen Kupplung und einer Standard-LC-Kupplung und
• 8 eine Gegenüberstellung der Querschnitte der erfindungsgemäßen Kupplung mit einer Standard-LC-Kupplung.

Some of them show schematically:

• 1 a perspective exploded view of a coupling according to the invention for connecting blow-in connectors,
• 2 according to a housing part of the clutch 1 in a front view and a top view,
• 3 the blow-in connector with optical fiber in a) perspective exploded view and b) assembled view,
• 4 a splice cassette for accommodating the coupling according to FIG 1 ,
• 5 a housing part for accommodating the blow-in plug,
• 6 the housing part according to 5 in further views,
• 7 another system of connection between the coupling according to the invention and a standard LC coupling and
• 8th a comparison of the cross sections of the coupling according to the invention with a standard LC coupling.

Components that are the same or have the same effect are provided with reference symbols in the following figures of the drawing based on an embodiment in order to improve legibility.

the end 1 shows an exploded view of a coupling 8 according to the invention for connecting optical waveguides.

The coupling 8 is designed for plugging in a plurality of blow-in plugs 20 to be connected to one another in order to form a plug-in connection of the optical fiber connections.

The optical waveguide can be a glass fiber and/or plastic fiber. The blow-in connector 20 is particularly suitable for connecting an optical fiber cable in a building in which the optical fiber cable is laid from distributors to the residential building in an empty conduit. The blow-in plug 20 is particularly suitable for laying in empty pipes with the smallest diameter. The blowing-in plug 20 can be blown through the empty tube by means of compressed air.

In order to enable the fiber optic cable to be laid through the empty conduit, the plug 20 has a number of parts, by means of which a fiber optic cable 2 is prefabricated, that is to say it is already realized ready for laying. These parts include a plug-in contact 1, which can preferably be pushed onto the free end 3 of the fiber optic cable 2, in particular onto the end of the fiber optic cable 2 that is not insulated.

The coupling 8 and the plug 20 form a system 10 for connecting fiber optic cables 2.

According to 3 the blow-in connector with fiber optic cable is shown in a) an exploded view and b) an assembled view.

The plug contact 1 has an in 3 shown ferrule holder 4, in which a Fer rule 5 for receiving the optical fibers of the fiber optic cable 2 is held. For this purpose, one end of the ferrule 5 , which is preferably designed as a thin tube, is pushed at least partially into the ferrule holder 4 . The fiber optic cable 2 can be glued into the ferrule holder 4 and into the ferrule 5.

The ferrule 5 has a polished section 31 at its free end 21; 3 b) clarified. The angle of inclination can be, for example, between 6° and 12°, in particular around 8°.

The plug contact 1 can have a press-on sleeve 32 which can be pressed onto the ferrule holder 4 . This press-on sleeve 32 is, for example, from the 1 , 3 and 5 out.

how 1 and 2 further show, the blow-in connector 20 also includes a lock 12a receiving the optical fiber cable 2 for connecting the plug contact 1 to the coupling 8. The lock 12a can be mounted on the plug contact 1 from the free end 3 thereof. The latch 12a is preferably made of a plastic such as polybutylene terephthalate (PBT).

An anti-twist device is formed between the lock 12a and the coupling 8 in the final assembled state of the plug 20 by a plug connection in the longitudinal direction of the optical fiber cable 2 between the locking 12a and coupling 8, so that the position of the optical fiber cable 2 in the final assembled state of the blow-in plug 20 in the coupling 8 is secured.

In particular, goes out 1 further shows that the plug-in connection between the lock 12a and the coupling 8 is formed by a lug or similar projection 6 of the lock 12a and by a complementary opening 7 in the coupling 8 . In the present embodiment, the lock 12a is formed with two lugs or similar projections 6 and the coupling 8 is formed with two openings 7 complementary thereto.

For a particularly secure and simple connection of the lock with the coupling, the plug-in connection between the lock 12a and the coupling 8 is designed in the manner of a bayonet connection, the lock 12a being rotated by means of the lugs or similar projections 6 in the manner of the bayonet catch by a rotary movement the clutch 8 is set in the openings 7.

The connection is thus made via a plug-and-turn movement: the two parts to be connected, i.e. the lock 12a and the coupling 8, are introduced into the openings 7 with the projections 6. The subsequent turning movement presses both parts against each other. A catch can also be used to further secure the connection.

From the 2 shows that the ferrule holder 4 on the coupling 8 in the final assembled state of the plug 20 is positively secured against twisting and for a clear positioning of the plug contact 1 of the blow-in plug 20 by corresponding wall sections of the coupling 8 and ferrule holder 4 that are non-circular in cross section. At least one section 22 of the inner circumference of the coupling 8 interacts with a corresponding section 23 of the outer circumference of the ferrule holder 4 . The section 22 of the coupling 8 is in 2 to be seen, the section 23 of the ferrule holder 4 is in particular in 1 , 3 and 5 apparent.

In the present exemplary embodiment, the section 22 of the inner circumference of the clutch 8 is a flat area along the inner surface of the clutch 8 (cf. 2 ) and the section 23 of the ferrule holder 4 of the blow-in connector 20 is designed as a corresponding flattening along the outer surface of the ferrule holder 4 (cf. 1 , 3 and 5 ). The anti-twist device is formed in this way, so that the fiber optic cable 2 is secured in a predetermined position in the coupling 8 in a torsion-proof manner in the final assembled state.

From the 1 and 2 It can also be seen that the clutch 8 is formed from two housing parts 9, 11 of identical construction in the present case. These housing parts 9, 11 can be connected to one another by means of a locking connection, with each housing part 9, 11 in the present embodiment having at least one locking lug 13 and at least one complementary locking eye 14, such as 1 further clarified. This locking connection can be detachable.

In the present embodiment according to 1 and 2 the housing parts 9, 11 have a centering aid for the assembly of the coupling 8, which in the present case is formed by a pin 16 which protrudes from the surface of one housing part 9 and which engages in a complementary opening 17 on the second housing part 11. According to 1 and 2 Both housing parts 9, 11 each have a pin 16 and a complementary opening 17. In this way, not only is a secure connection of both housing parts 9, 11 guaranteed but also the housing part 9, 11 can be designed as identical parts.

the 1 and 2 further show that each housing part 9, 11 has a plurality of insertion openings 18 for inserting the blow-in plug 20. Those insertion openings 18 of the fiber optic cables 2 to be connected face each other in the final assembled state of the coupling 8 . The shape of the plug-in openings 18 is adapted to the outer contour of the plug 20 for a secure hold of the plug 20 in the plug-in opening 18 .

From the 1 , 3 and 5 also shows that in the final assembled state of the plug 20 in the coupling 8 a compression spring 15 pre-assembled on the blow-in plug is prestressed, so that the position of the ferrule 5 and the blow-in plug 20 in the coupling 8 can be secured by the compression spring 15.

Due to the compression spring 15, the blow-in plug 20 can be displaced to a certain extent in the axial direction against the pressure of the spring relative to the unit composed of the locking device 12a and the coupling 8. For this purpose, the spring 15 can be supported with its one end against the ferrule flange and with its other end against the lock 12a.

Especially 1 shows that the coupling 8 for the connection of the fiber optic cables 2 has a slotted sleeve 30, in particular a ceramic sleeve, for centering the ferrules 5 in the coupling 8. This sleeve 30 is introduced into the housing parts 9, 11 of the coupling 8 in such a way that it surrounds the ferrules 5 of the blow-in plug 20 to be connected and is centered in the final assembled state. In the present case, the end of the housing parts 9, 11 opposite the insertion openings 18 of the housing parts 9, 11 has openings 25 for receiving the sleeve 30, as shown in particular in FIG 1 emerges.

In 4 an optical waveguide splice cassette 24 is shown, in which the coupling 8 is inserted.

The blow-in plug 20 described above can be accommodated not only on the coupling 8 described above but also on a housing part 19, in particular a standardized one.

3 and 5 show - in a schematic representation - a further possible embodiment of a blow-in connector 20 for a plug-in connection of optical fiber connections.

If plug 20 is accommodated in housing part 19 (cf. 5 and 6 ) the plug contact 1 or the blow-in plug 20, in particular the ferrule holder 4, is at least partially accommodated with the ferrule 5 in the housing part 19. The housing part 19 is, for example, a standardized housing part such as is usually used to connect fiber optic cables in communication systems.

In the present embodiment according to 5 and 6 the blow-in connector 20, in particular the ferrule holder 4, is held in the housing part 19 with the interposition of an adapter designed as a lock 12b. The lock 12b is preferably itself locked in a rotationally fixed manner within the housing part 19 . The ferrule holder 4 is secured against rotation by the corresponding plug contact section 23 in the housing part 19 .

It is also conceivable that the connection between the lock 12b and the housing part 19 is also designed in the manner of a bayonet connection in order to produce a particularly secure and simple connection of the lock 12b to the housing part 19 . Similar to the bayonet connection between the lock 12a and the coupling 8, the lock 12b can be fixed in openings by means of lugs or similar projections by a rotary movement relative to the housing part 19.

The latch 12b can be mounted on the plug contact 1 from the free end 3 thereof.

In particular, a plug housing can be formed by means of the housing part 19 and the lock 12b, such as that 5 and 6 demonstrate. Here, the lock 12b is connected to the housing part 19 in the longitudinal direction of the core cable 2 . In the present case, the lock 12b is designed with a slot 26 for snapping onto the wire cable 2 . Wire cables 2 assembled with plug connectors are designed with a secondary coating, for example, and have a diameter of 0.9 mm.

The slot 26 can be made very narrow for such an embodiment of the core cable 2 . However, fiber optic cables with other diameters, for example 2.4 mm or 3 mm, are also known. The slot 26 is therefore designed according to the application. Due to the connection of the closure cap or locking mechanism 12b to the housing part 19 in the longitudinal direction of the core cable 2, the compression spring 5 can be preloaded during the connection. As a result, particularly simple handling is possible. However, it is also conceivable to form the housing with two housing shells, in which the core cable 2 is embedded.

Such as from 5 and 6 is further seen, the latch 12b has a Anti-rotation relative to the housing part 19 on. For this purpose, the lock 12b preferably has at least one lug or the same projection 6 on at least one outer peripheral surface 29, which is received in a corresponding opening 7 in the housing part 19 when the housing part 19 is mounted on the lock 12b. A safeguard against displacement in the longitudinal direction of the optical fiber cable 2 is thus formed.

The latch 12b is preferably made of a plastic such as polybutylene terephthalate (PBT).

How out 5 It can also be seen that the ferrule holder 4 has an anti-twist device, which comes into the operative position with the locking mechanism 12b.

The anti-twist protection of the ferrule holder 4 is formed by at least a section of its outer surface, which enters into an operative position with a corresponding section of the inner circumference of the lock 12b. In this way, the ferrule holder 4 of the plug contact 1 is positively secured on the housing part 19 in the final assembled state of the plug 20 by corresponding wall sections 27 of the housing part 19 and ferrule holder 4, which are non-round in cross section, against twisting and for unambiguous positioning of the inlet plug 20. At least one section 27 of the inner circumference of the housing part 19 interacts with a corresponding section 23 of the outer circumference of the ferrule holder 4 (cf. 5 and 6 ).

From the 5 and 6 also shows that the plug 20 has a protective cap, in particular a dust cap 28 , which is pushed over the ferrule 5 and thus protects the free end of the ferrule 5 protruding from the housing part 19 . The protective cap 28 is detachably pushed onto the ferrule 5 and can be removed before plugging the plug 20 into the (not shown) corresponding socket or coupling of the house connection. The protective cap 28 is preferably pushed onto the ferrule 5 at the factory and is removed before the connection to the house connection is established.

• Es wird beispielsweise werkseitig das Lichtwellenleiterkabel 2 endseitig abisoliert und in den Ferrulenhalter 4 mit Ferrule 5 des Steckers 20 eingeführt und verklebt. Nach Aushärten eines Klebers kann im nächsten Arbeitsschritt das Anschleifen und Polieren der Stirnseite des Lichtwellenleiters erfolgen. Anschließend wird Staubschutzkappe 28 zum Schutz der Steckerstirnfläche aufgesteckt.

The blow-in connector 20 is assembled as follows:

• For example, the fiber optic cable 2 is stripped at the end at the factory and inserted into the ferrule holder 4 with the ferrule 5 of the connector 20 and glued. After an adhesive has hardened, the next step is to grind and polish the end face of the fiber optic cable. Dust cap 28 is then fitted to protect the end face of the connector.

These work steps can already be carried out at the factory, so that due to this prefabrication, the entire assembly effort for the connector 20 can be carried out much more cost-effectively and with much greater precision than before.

The cable prefabricated in this way is shifted through the empty tube (not shown) from a building connection to a distributor or vice versa, for example blown in by means of compressed air. The present connector 20 is designed as a blow-in connector.

The housing part 19, which is standardized in particular, is then mounted on site on the prefabricated plug 20 protruding from the empty pipe (not shown), with the interposition of the locking device 12b.

the end 7 shows another system of a connection between the clutch 8 according to the invention and another, in particular a standard LC clutch. In this embodiment, the clutch 8, in particular a housing part 9 of the clutch 8, can be connected to a housing part 35 of the further clutch, in particular the standard LC clutch. The LC connector or standard LC connector is one of the most common fiber optic connector types.

At the in 7 illustrated embodiment engages a locking eye 14 of the coupling half 9 in a locking lug 33 of the other coupling half and a locking lug 13 of the coupling half 9 in a locking eye 34 of the other coupling half. This system can also be referred to as a hybrid version of a coupling, since a blow-in connector 20, as described above, can be connected to a standard connector, in this case an LC connector. In the present exemplary embodiment, this hybrid coupling consists on one side of the connection for the blow-in plug 20 described above and on the other side of a connection for a standard plug, such as, e.g. B. an LC connector.

the end 8th shows a comparison of the cross sections of the clutch 8 according to the invention with a standard LC clutch.

Reference List

1

plug contact

2

fiber optic cable

3

free end plug contact

4

ferrule holder

5

ferrule

6

Tab - Connection Latch-Coupling

7

Opening - connection lock-clutch

8th

coupling

9

Housing part - clutch

10

system

11

Housing part - clutch

12a

Lock on coupling

12b

Lock on housing part

13

Latch - housing part

14

Locking eye - housing part

15

compression spring

16

pin on the housing part

17

corresponding opening on the housing part

18

insertion opening

19

housing part

20

blow-in connector

21

free end of the ferrule

22

Section locking clutch

23

corresponding section plug contact

24

Fiber optic splice cassette

25

opening for sleeve

26

slot

27

Housing part section

28

dust cap

29

outer peripheral surface

30

ceramic sleeve

31

grind

32

press-on sleeve

33

Detent further clutch

34

Locking eye further coupling

35

Housing part further clutch

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• US7104702B2 [0004]
• US 6550979 B1 [0004]
• US 6387018 B1 [0004]
• DE 102007033246 A1 [0004]
• DE 10342908 A1 [0007]
• EP 1450187 [0009]
• EP 2115509 A1 [0010]
• US 6572081 B2 [0012]
• US 2008/0317410 A1 [0013]
• EP 3258302 A1 [0016]
• DE 202014102537 A1 [0019]

Claims (18)

Coupling (8) for connecting optical fibers, at least two blow-in plugs (20) being insertable into the coupling (8) to form a plug-in connection of the optical fiber connections, and the blow-in plugs (20) having at least one plug-in contact (1), by means of which an optical fiber cable (2nd ) is pre-assembled at the factory and the plug contact (1) has a ferrule holder (4) in which a ferrule (5) for receiving the optical fibers of the optical fiber cable (2) is held, with the blow-in plug (20) having a lock receiving the optical fiber cable (2). (12a) for connecting the plug contact (1) to the coupling (8) and an anti-twist device between the lock (12a) and the coupling (8) in the final assembled state of the plug (20) through the plug connection in the longitudinal direction of the fiber optic cable (2) is formed between the lock (12a) and the clutch (8), so that the position of the optical fiber cable (2) in endmonti correct condition of the blow-in plug (20) in the coupling (8). clutch (8) after claim 1 , characterized in that the plug-in connection between the lock (12a) and the coupling (8) is formed by a nose or similar projection (6) of the lock (12a) and by a complementary opening (7) in the coupling (8), in particular that the coupling (8) is formed with two lugs or similar projections (6) and the lock (12a) is formed with two openings (7) complementary thereto. clutch (8) after claim 2 , characterized in that the plug-in connection between the lock (12a) and the coupling (8) is designed in the manner of a bayonet connection, the lock (12a) by means of the lugs or similar projections (6) in the manner of the bayonet closure by a rotary movement relative to the clutch (8) in the openings (7) can be fixed. Clutch (8) according to one of Claims 1 until 3 , characterized in that the plug contact (1) on the coupling (8) in the final assembled state of the plug (20) is positively secured against twisting and for unambiguous positioning of the plug contact (1) is secured in the coupling (8), at least one section (22) of the inner circumference of the coupling (8) having a corresponding section (23) of the outer circumference of the plug contact (1), in particular of the ferrule holder (4) of the plug contact (1), interacts. clutch (8) after claim 4 , characterized in that the section (22) of the inner circumference of the coupling (8) as a flattening along the inner surface of the coupling (8) and the section (23) of the plug contact (1), in particular of the ferrule holder (4) as a corresponding flattening along the Lateral surface of the plug contact (1) are designed for an anti-twist device, so that the fiber optic cable (2) in the final assembled state is secured against twisting in a predetermined position in the coupling (8). Clutch (8) according to one of Claims 1 until 5 , characterized in that it is formed from two housing parts (9, 11), in particular of identical construction. clutch (8) after claim 6 , characterized in that the housing parts (9, 11) can be connected to one another by means of a latching connection, each housing part (9, 11) having at least one latching lug (13) and at least one complementary latching eye (14). Coupling (8) according to one of the preceding claims, characterized in that in the final assembled state of the plug (20) in the coupling (8) a compression spring (15) pre-assembled on the blow-in plug is pretensioned and the position of the ferrule (5) and the blow-in plug ( 20) can be secured in the clutch (8) by the compression spring (15). Coupling (8) according to one of the preceding claims, characterized in that the housing parts (9, 11) have a centering aid for mounting the coupling (8), the centering aid being provided by at least one pin protruding from the surface of one housing part (9). (16) which engages in a complementary opening (17) on the second housing part (11) when the housing parts (9, 11) are connected to one another, in particular that both housing parts (9, 11) have at least one pin (16) and a complementary Have opening (17). Coupling (8) according to one of the preceding claims, characterized in that each housing part (9, 11) has at least one plug-in opening (18) for plugging in the plug (20), the plug-in openings (18) extending from the optical fiber cables (2nd ) are opposite in the final assembled state of the coupling (8) and the shape of the insertion openings (18) is adapted to the outer contour of the plug (20) for a secure hold of the plug (20) in the insertion opening (18). Coupling (8) according to one of the preceding claims, characterized in that the coupling (8) for the connection of the fiber optic cables (2) each have a preferably slotted sleeve (30), in particular a ceramic sleeve, for centering the ferrules (5), the sleeve (30) being introduced into the housing parts 9, 11 of the coupling 8 in such a way that it surrounds the ferrules 5 of the blow-in plug 20 to be connected and is centered in the final assembled state. Coupling (8) according to one of the preceding claims, characterized in that the outer shape of the coupling (8) is designed in such a way that the coupling (8) can be inserted into an optical fiber splice cassette (24). Coupling (8) according to one of the preceding claims, characterized in that it is made of plastic, for example polybutylene terephthalate (PBT). System (10) for connecting fiber optic cables (2) with a coupling (8) according to one of Claims 1 until 13 and with at least one blow-in plug (20). system (10) according to Claim 14 , characterized in that the blow-in connector (20) for a plug connection of fiber optic connections has at least one plug contact (1), by means of which the fiber optic cable (2) is prefabricated at the factory, the plug contact (1) having a ferrule holder (4) in which a Ferrule (5), the plug (20) having a lock (12a, 12b) accommodating the fiber optic cable (2) for connecting the plug contact (1) to a coupling (8) or to a housing part (19), in particular a standardized one Housing part for the plug (20) for connection to a socket or similar receiving part, wherein the lock (12a, 12b) can be mounted on the plug contact (1) from its free end (3) and with an anti-twist device between the lock (12a, 12b) and the coupling (8) or the housing part (19) in the final assembled state of the plug (20) by a plug connection between the lock (12) and the coupling (8) or he housing part (19) is formed. system (10) according to Claim 14 or 15 , characterized in that the clutch (8), in particular a housing part (9) of the clutch (8) with a housing part (35) of a further clutch, in particular a standard LC clutch, can be connected, with a connection preferably having at least one locking lug (33) of the housing part (35) of the further coupling in a locking eye (14) of the housing part (9) of the coupling (8) and/or at least one locking lug (13) of the housing part (9) of the coupling (8) in a locking eye (34) of the housing part (35) of the further clutch engages. Fiber optic splice cassette (24) for connecting fiber optic cables (2) to a coupling (8) according to one of Claims 1 until 13 for accommodating several blow-in plugs (20) for a plug-in connection of the fiber optic connections. Optical fiber splice box with at least one optical fiber splice cassette (24). Claim 17 .

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