DE102021134112B3 - Ferrule for a fiber optic cable, ferrule assembly and connector assembly - Google Patents

Abstract

A ferrule (20) for a fiber optic cable (12) has a base body (26), a cover (28) and a spring clip (30) by means of which the cover (28) is attached to the base body (26). The base body (26) has a pin receptacle (24) for a pin (22) extending in the axial direction (A) for connecting the ferrule (20) to a second ferrule (20). The spring clip (30) has a spring arm (41) which projects into the pin receptacle (24) and is set up to prestress the pin (22) in the radial direction (V) into the pin receptacle (24) when the pin (22 ) is used in a connector position in the pin receptacle (24) to connect the ferrule (20) to a second ferrule (20). A ferrule assembly and a plug assembly are also provided.

Description

The invention relates to a ferrule for a fiber optic cable, with a base body, a cover and a spring clip, by means of which the cover is attached to the base body, the base body having a pin receptacle for a pin extending in the axial direction for connecting the ferrule to a second ferrule . The invention also relates to a ferrule assembly with such a ferrule and a connector assembly with such a ferrule assembly.

Ferrules for fiber optic cables are known.

It is also known to attach a cover to a base body of the ferrule by means of a spring clip or a clamp.

To transmit signals from one fiber optic cable to another fiber optic cable, two ferrules are usually connected to a connector assembly using two pins to secure and align the two ferrules together.

In order to ensure the best possible signal transmission, it is necessary for the glass fibers of the glass fiber cable to be arranged very precisely in the ferrules and for the two ferrules of the connector assembly to be aligned in a well-defined manner.

In the WO 2009/010210 A1 a fiber optic duplex connector with a ferrule is shown.

The object of the invention is to provide a ferrule for a glass fiber cable, a ferrule assembly and a connector assembly that reliably ensures particularly good signal transmission.

The object is achieved by a ferrule for a fiber optic cable, with a base body, a cover and a spring clip, by means of which the cover is attached to the base body. The base body has a pin receptacle for a pin extending in the axial direction for connecting the ferrule to a second ferrule. Furthermore, the spring clip has a spring arm projecting into the pin receptacle, which is set up to prestress the pin in the radial direction into the pin receptacle when the pin is inserted in the pin receptacle in a plug position in order to connect the ferrule to a second ferrule. The spring arm protrudes into the pin receptacle at least without the inserted pin, i.e. the spring arm can be pushed out of the pin receptacle at least in sections by the pin inserted. In terms of the invention, the connector position is an axial position relative to the base body, in which the pin is preferably located when the ferrule is connected to a second ferrule.

According to the invention, it was recognized that the pin can be pressed into the pin receptacle in a defined manner by means of the spring arm and can thus be effectively aligned in it. This reliably ensures that the ferrules and thus the glass fibers fastened in the ferrules are arranged precisely in relation to one another when the ferrule is combined with another ferrule using the pin to form a connector assembly. In this way, coupling losses are reduced and thus signal transmission with a particularly high quality is guaranteed.

In one embodiment, the spring clip has clamp arms that prestress the cover in the vertical direction relative to the base body. In this case, the vertical direction is a direction that is transverse to the axial direction, in particular perpendicular. Due to the pretensioning, the cover is pressed against the base body with a defined pressure and is thus fastened to it reliably and without play.

In this case, the base body and/or the cover can have a glass fiber receptacle for receiving the glass fibers of the glass fiber cable. The ferrule is designed in such a way that the glass fibers are pressed laterally into the glass fiber holder by means of the spring clip when the glass fibers are inserted in the glass fiber holder. In this way, the pressure applied by the pretension is used to precisely align the glass fibers in the glass fiber holder, which ensures signal transmission with a particularly high quality.

Furthermore, a pressure piece which is prestressed by the spring clip and presses the glass fibers into the glass fiber receptacle can be provided between the glass fibers and the spring clip. By means of the pressure piece, the pressure by means of which the glass fibers are pressed into the glass fiber holder can be determined particularly precisely, in particular for large temperature ranges in which the glass fiber holder and the glass fiber expand to different extents due to the different materials. The pressure on the glass fibers is a key factor that determines the signal quality.

In addition or as an alternative, it can be provided that the base body and the cover each have a glass fiber receptacle for accommodating a proportion of the glass fibers of the glass fiber cable. In this case, the ferrule has an intermediate piece which is arranged between the glass fiber mount of the base body and the glass fiber mount of the cover. As a result, the glass fibers can be arranged in several levels in the ferrule, so that the Ferrule is designed particularly compact, even if it is designed for a fiber optic cable with a large number of fibers.

According to one embodiment, the adapter has a fiber optic receptacle for accommodating a portion of the fiber optics of the fiber optic cable, whereby the number of levels can be increased further in an efficient manner.

According to a further embodiment, the spring clip has a retaining finger which fixes the pin in the axial direction in the pin receptacle when the pin is inserted in the pin receptacle in the plug position. This ensures that the pin reliably remains in the plug position, in particular when the ferrule is connected to another ferrule by means of the pin and then disconnected from one another again.

It can be provided here that the holding finger is arranged on a second spring arm of the spring clip. The ferrule is designed in such a way that the second spring arm is deflected into a tensioned position when the pin is pushed into the pin receptacle in the axial direction into the plug position. In this way, the retaining finger is reliably biased by the spring arm into a position that ensures that the pin is fixed in the pin receptacle in the axial direction by the retaining finger.

Additionally or alternatively, the spring clip can have a central, flat central section, from which spring arms protrude laterally at opposite edges and these run curved in a C-shape to the base body. The freely ending section of the "C" forms a locking end of the respective spring arm, with which it presses against the pin or the base body or cover. This design has the advantage that the preload or the pressure that the spring arms exert on the pin, the base body and/or the cover can be set particularly precisely, in particular for large temperature ranges. Furthermore, the detents of the spring arms are particularly well protected by this design, particularly when the free-ended portions of the "C" point inwards, i.e. towards a plane which extends through the center section in the axial direction and perpendicular to the center section. In this way, the locking ends cannot be unintentionally bent or deflected when handling the ferrule, in particular when plugging it in with or detaching it from another ferrule.

According to the invention, a ferrule assembly with a ferrule according to the invention with a holding finger and a pin for connecting the ferrule to a second ferrule is also provided to solve the above-mentioned object. The pin has an indentation into which the retaining finger engages when the pin is inserted in the connector position in the pin receptacle. In the context of the invention, a recess is in particular a circumferential groove. This ensures that the retaining finger reliably fixes the pin in the axial direction in the pin receptacle, regardless of the orientation in which the pin is pushed or inserted into the pin receptacle in the circumferential direction.

Furthermore, according to the invention, to achieve the above-mentioned object, a connector assembly is also provided with a ferrule according to the invention, which forms a female connector, and a ferrule assembly according to the invention, which forms a male connector. The ferrule and the ferrule assembly are connected to one another by means of the pin of the ferrule assembly in such a way that the glass fibers of a glass fiber cable fixed in the ferrule are connected in a signal-transmitting manner to the glass fibers of a glass fiber cable fixed in the ferrule assembly. Due to the precise arrangement of the pins and the glass fibers within the ferrules and due to the precise alignment of the ferrules to each other via the pin, coupling losses are kept low and thus signal transmission with a particularly high quality is guaranteed.

In one embodiment, the connector assembly has a first position in which the ferrule and ferrule assembly are operatively coupled to one another in a 0°/0° orientation and a second position in which the ferrule and ferrule assembly are in a 0°/180° orientation -Alignment are coupled to each other in a signal-transmitting manner. According to the invention, the 0°/180° alignment differs from the 0°/0° alignment in that one of the ferrules is rotated 180° in the circumferential direction relative to the other ferrule about an axis that extends in the axial direction . As a result, the connector assembly is designed to couple the glass fibers to one another in a signal-transmitting manner both in the 0°/0° orientation and in the 0°/180° orientation. The connector assembly can thus be used particularly flexibly in order to couple glass fibers to one another in a signal-transmitting manner.

Additionally or alternatively, the plug assembly can include a spring clip. Here, the connector assembly has a locked position in which the spring clip axially biases and secures the ferrule and ferrule assembly together, and an open position in which the ferrule and ferrule assembly are axially non-destructively separable. In the locked position, the spring clip thus ensures that the ferrules are sealed in the axial direction abut one another, whereby only very low coupling losses occur at the transition from an optical fiber to an associated optical fiber, which are coupled in a signal-transmitting manner by means of the connector assembly.

• - 1 in einer perspektivischen Darstellung eine erfindungsgemäße Ferrulenbaugruppe,
• - 2 in einer perspektivischen Darstellung eine erfindungsgemäße Ferrule,
• - 3 in einer perspektivischen Darstellung einen Grundkörper der Ferrulenbaugruppe aus 1,
• - 4 in einer perspektivischen Darstellung einen Grundkörper mit einem Deckel der Ferrulenbaugruppe aus 1,
• - 5 in einer perspektivischen Darstellung einen Federclip der Ferrulenbaugruppe aus 1,
• - 6 in einer perspektivischen Schnittansicht einen Abschnitt der Ferrulenbaugruppe aus 1,
• - 7 in einer perspektivischen Darstellung eine erfindungsgemäße Steckerbaugruppe, die aus der Ferrulenbaugruppe aus 1 und der Ferrule aus 2 gebildet ist, in einer 0°/0°-Ausrichtung,
• - 8 in einer perspektivischen Darstellung die Steckerbaugruppe aus 7 in einer 0°/180°-Ausrichtung,
• - 9 in einer Draufsicht eine erfindungsgemäße Ferrulenbaugruppe gemäß einer weiteren Ausführungsform, wobei der Federclip nicht dargestellt ist, und
• - 10 in einer Draufsicht eine erfindungsgemäße Ferrulenbaugruppe gemäß einer weiteren Ausführungsform, wobei der Federclip nicht dargestellt ist.

Further advantages and features emerge from the following description and from the accompanying drawings. In these show:

• - 1 a perspective view of a ferrule assembly according to the invention,
• - 2 a perspective view of a ferrule according to the invention,
• - 3 in a perspective representation of a base body of the ferrule assembly 1 ,
• - 4 in a perspective representation of a base body with a cover of the ferrule assembly 1 ,
• - 5 shows a perspective view of a spring clip of the ferrule assembly 1 ,
• - 6 Figure 12 shows a sectioned perspective view of a portion of the ferrule assembly 1 ,
• - 7 in a perspective view of a connector assembly according to the invention, which consists of the ferrule assembly 1 and the ferrule 2 is formed in a 0°/0° orientation,
• - 8th shows the connector assembly in a perspective view 7 in a 0°/180° orientation,
• - 9 in a plan view a ferrule assembly according to the invention according to a further embodiment, wherein the spring clip is not shown, and
• - 10 in a plan view a ferrule assembly according to the invention according to a further embodiment, wherein the spring clip is not shown.

In 1 A ferrule assembly 10 for a fiber optic cable 12 is shown. The ferrule assembly 10 has a ferrule 20 and two pins 22 which are each arranged in a pin receptacle 24 of the ferrule 20 and extend in the axial direction A.

In the illustrated embodiment, the pins 22 are in a plug position in the pin receptacle 24 in the axial direction A, so that the ferrule assembly 10 forms a male plug which is connected to a female plug in the form of a further ferrule 21 (see FIG 2 ) can be coupled in order to signal-connect the optical fiber cable 12 to an optical fiber cable 13 fixed in the ferrule 21, as will be explained later.

The ferrule 20, which forms the male connector together with the pins 22, and the ferrule 21, which forms the female connector, have an identical design.

The structure of the ferrule 20 is described below by way of example, which applies in an analogous manner to the structure of the ferrule 21 .

The ferrule 20 has a body 26 and a cover 28 which together form a housing 29 and a spring clip 30 which secures the cover 28 to the body 26.

The pin receptacles 24 are formed in the base body 26 and ensure a defined alignment of the pins 22 in the ferrule 20.

Between the pin receptacles 24, the base body 26 has a glass fiber receptacle 32 (see 3 ), in which the glass fibers 34 of the glass fiber cable 12 are accommodated, and a glass fiber cable receptacle 36 in which the glass fiber cable 12 is accommodated.

In this case, the glass fiber receptacle 32 is adjacent to an axial end of the ferrule 20 which forms a coupling section 38 of the ferrule 20 on the end face.

The base body 26, the cover 28, the spring clip 30 and the pins 22 are made of a heat-resistant material, in particular a metal, whereby the ferrule 20 and the ferrule assembly 10 can be used in a wide temperature range, in particular between -40° C. and 150℃

For this purpose, the base body 26, the cover 28 and the spring clip 30 can each be formed from a material with a thermal expansion coefficient of 15×10 −6 [1/K] to 25×10 −6 [1/K].

Furthermore, for this purpose, the pins 22 can be formed from a material with a thermal expansion coefficient of 13×10 −6 [1/K] to 20×10 −6 [1/K].

Furthermore, for this purpose, the glass fibers 34 can be formed from a material with a thermal expansion coefficient of 3×10 −7 [1/K] to 7×10 −6 [1/K].

The spring clip 30 has a center portion 40 extending in the axial direction A (see FIG 5 ) And a plurality of spring arms 41, 42, 43, in the form of first spring arms 41, second spring arms 42 and third spring arms 43 on each other opposite lateral edges 46, 47 of the center portion 40 protrude.

The spring arms 41, 42, 43 are arranged in pairs, i.e. mirror-symmetrically to the central section 40.

Furthermore, the spring arms 41, 42, 43, viewed in the axial direction A, extend in a C-shape in the direction of the base body 26 or, in the case of the first spring arms 41, around it.

Each of the spring arms 41, 42, 43 has a locking end 48 which is formed by the free-ended section of the "C", i.e. the end of the spring arms 41, 42, 43 which is opposite to the central section 40.

The first spring arms 41 rest with their locking ends 48 laterally and directly on one of the pins 22 and press the corresponding pin 22 in the vertical direction V into the pin receptacle 24 (see FIG 6 ).

If no pins 22 are arranged in the pin receptacles 24, in particular in the connector positions, the locking ends 48 protrude into the pin receptacles 24, so that the pins 22 deflect the locking ends 48 of the first spring arms 41 into a tensioned position counter to the vertical direction V when the pins 22 are pushed in the axial direction A into the pin receptacles 24, in particular into the connector positions.

As a result, the pins 22 are pretensioned in the connector position by means of the first spring arms 41 in the radial direction, i.e. perpendicular to the axial direction A, into the pin receptacle 24 and are thus precisely aligned with respect to the base body 26.

For this purpose, the cover 28 has a recess 50 (see FIG 4 ) through which the first spring arms 41 protrude into the pin receptacle 24 or into contact with the pins 22 in the pin receptacle 24, in particular in the connector position.

The second spring arms 42 protrude through the recesses 50 with their arresting end 48, which acts as a retaining finger 52 (see FIG 5 ) is formed, in each case in one of the pin receptacles 24.

The locking ends 48 of the second spring arms 42 are designed as retaining fingers 52 which engage in a complementarily designed recess 54 in the pin 22 when the pin 22 is inserted in the plug position in the corresponding pin receptacle 24 . As a result, the pins 22 are fixed in the plug position in the axial direction A in the pin receptacles 24 by means of the second spring arms 42 .

When the pins 22 are pushed into the pin receptacles 24, the retaining fingers 52 are deflected counter to the vertical direction V into a clamped position and then snap into the recesses 54 in the vertical direction V as soon as the pins 22 have reached the connector position.

The third spring arms 43 form clamp arms 56, by means of which the cover 28 is attached to the base body 26.

The locking ends 48 of the third spring arms 43 press the cover 28 and the base body 26 together in the vertical direction V into a prestressed position.

In the present embodiment, the spring clip 30 has two pairs of first spring arms 41, one pair of second spring arms 42, and two pairs of third spring arms 43.

In this case, a pair of the third spring arms 43 is arranged on the axial ends of the spring clip 30, while the pair of the second spring arms 42 is arranged in the axial direction A between each pair of the first spring arms 41.

In principle, the spring clip 30 can have any number of spring arms 41, 42, 43, but at least one first spring arm 41.

Additionally or alternatively, the spring arms 41, 42, 43 can be arranged in any way in an alternative embodiment, as long as they fulfill their function explained above.

In this connection, the housing 29 has a spring clip receptacle 58 designed to complement the spring clip 30 (see FIG 4 ), in which the spring clip 30 is accommodated and is thereby arranged in a defined manner in relation to the housing 29, in particular in the axial direction A.

Thus, in the connector position, the pins 22 are arranged precisely opposite the coupling section 38 in the axial direction A by means of the spring clip 30 .

In an alternative embodiment, spring clip receptacle 58 may be part of either base 26 or cover 28 .

Furthermore, the cover 28 has a pressure section 60 which is arranged opposite the glass fiber holder 32 and is prestressed in relation to the glass fiber holder 32 by means of the spring clip 30 .

In the present embodiment, the ferrule 20 also has a pressure piece 62 that between tween the glass fiber receptacle 32 and the pressure section 60 is arranged.

The glass fibers 34 arranged in the glass fiber receptacle 32 are pressed laterally into the glass fiber receptacle 32 in the vertical direction V by means of the pressure section 60 via the pressure piece 62 and are thus aligned in a defined manner with respect to the base body 26 .

The glass fiber cable 12 here has 16 glass fibers 34 and the glass fiber receptacle 32 has a corresponding number of recesses or holders.

Of course, in an alternative embodiment, the glass fiber cable 12 can have any number of glass fibers 34 and the glass fiber receptacle 32 can have a corresponding number of recesses or holders.

In an alternative embodiment, the fiber optic cable 12 has at least two glass fibers.

The glass fibers 34 are arranged here in a horizontal plane which extends perpendicularly to the vertical direction V.

In an alternative embodiment, the glass fiber receptacle 32 is arranged in the cover 28 . In this case, the section of the base body 26 opposite the glass fiber receptacle 32 forms a corresponding pressure section 60 by means of which the glass fibers 34 are pressed laterally into the glass fiber receptacle 32 .

In a further alternative embodiment (see 9 ) the base body 26 has a glass fiber mount 32 for a first portion of the glass fibers 34 of the glass fiber cable 12 and the cover 28 has a second glass fiber mount 64 for a second portion of the glass fibers 34.

In this case, the pressure piece 62 is arranged in the vertical direction V between the glass fiber mount 32 of the base body 26 and the second glass fiber mount 64, so that the first portion of the glass fibers 34 in the vertical direction V into the glass fiber mount 32 and the second portion of the glass fibers 34 against the vertical direction V in the second glass fiber receptacle 64 by means of the spring clip 30 are biased.

In a further alternative embodiment (see 10 ) The ferrule 20 has an adapter 66 with a third optical fiber receptacle 68 for a third portion of optical fibers 34 and a fourth optical fiber receptacle 70 for a fourth portion of optical fibers 34, which are arranged in the vertical direction V on opposite sides of the adapter 66.

The intermediate piece 66 is arranged in the vertical direction V between the glass fiber mount 32 of the base body 26 and the second glass fiber mount 64, so that the glass fiber mount 32 and the third glass fiber mount 68 and the fourth glass fiber mount 70 and the second glass fiber mount 64 are opposite in the vertical direction V.

In this connection, the ferrule 20 has a pressure piece 62 which is arranged between the glass fiber receptacle 32 of the main body 26 and the third glass fiber receptacle 68, and a second pressure piece 72 which is arranged between the second glass fiber receptacle 64 and the fourth glass fiber receptacle 70. The portions of the glass fibers 34 are thus prestressed in the vertical direction V by the spring clip 30 by means of the intermediate piece 66 and the pressure pieces 62, 72 in the corresponding glass fiber receptacles 32, 64, 68, 70.

In the present embodiment, the link 66 has a horizontally extending intermediate pressure piece 74 separating the side of the link 66 with the third optical fiber receptacle 68 from the side of the link 66 with the fourth optical fiber receptacle 70 in the vertical direction.

In an alternative embodiment, the intermediate piece 66 has only a single glass fiber receptacle 68, 70.

Additionally or alternatively, the ferrule 20 can have any number of spacers 66 .

In the illustrated embodiments, 16 glass fibers 34 are arranged in each of the glass fiber receptacles 32, 64, 68, 70.

Of course, in all embodiments, any number of glass fibers 34 can be accommodated in the glass fiber receptacles 32, 64, 68, 70, in particular at least two glass fibers 34 per glass fiber receptacle 32, 64, 68, 70.

What all the embodiments have in common is that the glass fibers 34 and the pins 22 are precisely aligned with respect to the base body 26 and have a clearly defined position on the coupling section 38 .

The ferrule assembly 10 is connected to the ferrule 20 by means of pins 22 to form a connector assembly 80 (see FIG 7 ) can be coupled.

For this purpose, the ferrule 20 is pushed onto the ferrule assembly 10 in the axial direction A until the coupling sections 38 of the ferrules 20, 21 rest against one another.

The ferrule assembly 10 forms a male connector and the ferrule 20 forms a female connector of complementary design, which are plugged together by means of the pins 22 .

In this plugged-in position, the glass fibers 34 of the glass fiber cable 12 are arranged precisely opposite the glass fibers 34 of the glass fiber cable 13 and are thus connected in a signal-transmitting manner with low coupling losses.

In order to ensure that the coupling sections 38 lie tightly against one another in the axial direction A, the plug assembly 80 has a spring clip 82 .

The spring clip 82 is attached to the housing 29 of the ferrule assembly 10 such that it can pivot.

The connector assembly 80 has a locked position (see 7 ), in which the spring clip 82 is latched with latching elements 84 in the form of two pins on the ferrule 21 and thus the ferrule assembly 10 is fixed to the ferrule 21.

In this context, the plug assembly 80 is designed such that the spring clip 82 in the locked position biases the ferrule assembly 10 and the ferrule 21 in the axial direction A, whereby the coupling sections 38 of the ferrule assembly 10 and the ferrule 21 are pressed against one another in the axial direction.

By separating the spring clip 82 from the latching elements 84 and folding it away from the ferrule 21, the lock is released and the plug assembly 80 is moved into an open position in which the ferrule 21 can be pulled off the ferrule assembly 10 in the axial direction A in order to to detach the plug connection non-destructively.

Of course, in an alternative embodiment, the spring clip 82 may be pivotally attached to the ferrule 21, i.e. the female connector.

The 7 Figure 12 shows the connector assembly in a first position in which the ferrule assembly 10 and ferrule 21 are signal-coupled together in a 0°/0° orientation.

Furthermore, the ferrule assembly 10 has a second position (see FIG 8th ), in which the ferrule 21 is rotated by 180° relative to the first position in the circumferential direction U and thus the ferrule assembly 10 and the ferrule 21 are coupled to one another in a 0°/180° orientation in a signal-transmitting manner.

In other words, the ferrule 21 can be plugged together with the ferrule assembly 10 either normally or rotated by 180°, with the glass fibers 34 of the glass fiber cables 12, 13 being coupled to one another in a signal-transmitting manner in both positions, although the assignment of the glass fibers 34 differs in the first position differs from the second position.

In this way, a ferrule 20, 21, a ferrule assembly 10 and a connector assembly 80 is provided which ensure a particularly precise arrangement of the glass fibers 34 in the ferrule 20, 21 itself and the ferrules 20, 21 to one another and thus ensure that the coupling losses are low and thus the quality of the signal transmission is particularly high.

The invention is not limited to the embodiments shown. In particular, individual features of an embodiment can be combined as desired with features of other embodiments, in particular independently of the other features of the corresponding embodiments.

Claims (13)

Ferrule (20, 21) for a fiber optic cable (12, 13), with a base body (26), a cover (28) and a spring clip (30) by means of which the cover (28) is attached to the base body (26), wherein the base body (26) has a pin receptacle (24) for a pin (22) extending in the axial direction (A) for connecting the ferrule (20, 21) to a second ferrule (20, 21), characterized in that the spring clip (30) has a spring arm (41) which projects into the pin receptacle (24) and is designed to prestress the pin (22) in the radial direction (V) into the pin receptacle (24) when the pin (22) is in a plug position is inserted into the pin receptacle (24) in order to connect the ferrule (20, 21) to a second ferrule (20, 21). Ferrule (20, 21) to claim 1 , characterized in that the spring clip (30) has clamp arms (56) which bias the cover (28) in the vertical direction (V) relative to the base body (26). Ferrule (20, 21) to claim 2 , characterized in that the base body (26) and / or the cover (28) has a glass fiber receptacle (32) for receiving the glass fibers (34) of the glass fiber cable (12, 13), the ferrule (20, 21) so is designed such that the glass fibers (34) are pressed laterally into the glass fiber receptacle (32) by means of the spring clip (30) when the glass fibers (34) are inserted into the glass fiber receptacle (32). Ferrule (20, 21) to claim 3 , characterized in that between glass fibers (34) and spring clip (30) is provided by the spring clip (30) prestressed pressure piece (62) which presses the glass fibers (34) into the glass fiber receptacle (32). Ferrule (20, 21) to claim 3 or 4 , characterized in that the base body (26) and the cover (28) each have a glass fiber receptacle (32) for receiving a portion of the glass fibers (34) of the glass fiber cable (12, 13), the ferrule (20, 21) having an intermediate piece (66) which is arranged between the glass fiber receptacle (32) of the base body (26) and the glass fiber receptacle (64) of the cover (28). Ferrule (20, 21) to claim 5 , characterized in that the intermediate piece (66) has a glass fiber receptacle (68, 70) for receiving a portion of the glass fibers (34) of the glass fiber cable (12, 13). Ferrule (20, 21) according to one of the preceding claims, characterized in that the spring clip (30) has a retaining finger (52) which fixes the pin (22) in the axial direction (A) in the pin receptacle (24) when the Pin (22) is inserted in the connector position in the pin receptacle (24). Ferrule (20, 21) to claim 7 , characterized in that the retaining finger (52) is arranged on a second spring arm (42) of the spring clip (30), the ferrule (20, 21) being designed in such a way that the second spring arm (42) is deflected into a tensioned position when the pin (22) is inserted in the axial direction (A) into the connector position in the pin receptacle (24). Ferrule (20, 21) to claim 7 or 8th , characterized in that the spring clip (30) has a central, flat central section (40), from which spring arms (41, 42, 43) protrude laterally at opposite edges (46, 47) and these are bent in a C-shape to the base body (26 ) run, with the free-ending section of the "C" forming a locking end (48) of the respective spring arm (41, 42, 43), with which it presses against the pin (22) or the base body (26) or cover (28). . Ferrule assembly (10) with a ferrule (20, 21) according to one of Claims 7 until 9 and a pin (22) for connecting the ferrule (20, 21) to a second ferrule (20, 21), characterized in that the pin (22) has a recess (54) into which the holding finger (52) engages, when the pin (22) is inserted in the plug position in the pin receptacle (24). Connector assembly (80) with a female connector forming ferrule (20, 21) according to any one of Claims 1 until 9 and a ferrule assembly (10) forming a male connector claim 10 , wherein the ferrule (20, 21) and the ferrule assembly (10) are connected to one another by means of the pin (22) of the ferrule assembly (10) in such a way that the glass fibers (34) of a glass fiber cable (12 , 13) are connected in a signal-transmitting manner to the glass fibers (34) of a glass fiber cable (12, 13) fixed in the ferrule assembly (10). connector assembly (80). claim 11 , characterized in that the plug assembly (80) has a first position in which the ferrule (20, 21) and the ferrule assembly (10) are signal-transmissively coupled to one another in a 0°/0° orientation, and a second position in wherein the ferrule (20, 21) and the ferrule assembly (10) are communicatively coupled to one another in a 0°/180° orientation. connector assembly (80). claim 11 or 12 , comprising a spring clip (82), the plug assembly (80) having a locked position in which the spring clip (82) biases the ferrule (20, 21) and the ferrule assembly (10) in the axial direction (A) and secures them together, and has an open position in which the ferrule (20, 21) and the ferrule assembly (10) can be separated from one another in the axial direction (A) without being destroyed.

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