DE102005063437B4 - Optical connector and use for it - Google Patents

Abstract

The invention relates to an optical connector with axial tolerance compensation for an optical connection, comprising at least one socket (200) having a housing (210), an optical device (230) and a latching device (212), and at least one to the socket (200). corresponding connector (100) comprising a housing (110), an optical device (130), an outer, at least partially encircling locking bracket (112, 112 ') and an optical fiber seal (150), wherein the locking bracket (112, 112') as a separate part is formed on the housing (110) of the plug (100) and can be supported on the latching device (212) in such a way that the optical device (130) can be moved directly against the optical device (110) via the optical waveguide seal (150) from the housing (110). 230), and in a mated condition of the plug (100) with the socket (200), the optical device (130) abuts the optical device (230), and the like nd by the interaction of the locking bracket (112, 112 ') with the optical waveguide seal (150) and the latching device (212), the optical device (130) with an axial tolerance compensation realizing, mechanical bias in an axial direction (A), at the optical Device (230) is applied.

Description

The invention relates to a waterproof optical connector with tolerance compensation, especially for the automotive sector. Furthermore, the invention relates to a use of an optical connector in a video link system, a camera system or an optical or opto-electrical coupling.

For detachable connections in the field of optical transmission technology connectors are used. In most optical connectors, the fiber ends of optical fibers are joined together at their end faces. Here, an axial distance, a radial offset and an angular offset of the fiber ends should be as small as possible in order to minimize insertion loss and backscatter attenuation of an optical signal. In order to prevent an axial distance between the two fiber ends of the optical waveguide, an axial tolerance compensation for the fiber ends is necessary for an optical connector, so that they rest with a maximum possible Faserendflächenüberdeckung to each other form fit.

This is what the US Pat. No. 6,416,233 B2 and the US 5 719 977 A each an optical connector for a bidirectional channel with two optical fibers, each with an axial tolerance compensation for at least one fiber end of an optical waveguide. The respective end sections of the optical waveguides to be coupled together have an optical ferrule, also called a ferrule, wherein at least one optical ferrule of two optical waveguide ends to be optically coupled is pressed against the respective optical ferrule of the other optical waveguide by means of a helical compression spring. Furthermore, the US 5 076 656 A and the US 4,687,291 A. also in each case an optical connector for a bidirectional optical fiber channel. In each case, two ferrules of the relevant optical waveguide ends to be coupled are accommodated in a sleeve, which can perform a tumbling movement about its center. The end portions of the respective ferrules and the corresponding insertion portions of the sleeve for ferrules have corresponding cone portions to each other. As a result, a lying on a straight line, simultaneously centered joining the end portions of two optical fibers is realized. Each of the ferrules is resiliently biased against the respective other ferrule.

The US 4,747,656 A discloses an optical connector between a socket with a diode and a connector with ferrule, wherein in the assembled state of the plug and socket the ferrule rests against the diode and the plug can engage with radially movable spring segments behind a shoulder of the socket and so the plug to the socket holds. It is also possible to form the movable segments on the socket and the shoulder on the plug. In a further development, the plug also has a rotatable sleeve, by means of which the connector can be secured.

The DE 698 16 292 T2 discloses an optical connector with an adapter, wherein from two opposite sides optical plug can be inserted into the adapter and within the adapter optical end sleeves of the plug are centered to each other. The respective optical end sleeve of a plug is biased by a spiral spring to realize a mechanical contact of the optical end sleeves with a certain bias within the optical connector.

For a realization of the smallest possible lateral offset, an axial tolerance compensation and a small angular offset of the fiber cores of fiber optic connectors, a large number of individual parts are needed in the prior art, which are also structurally complex in some cases. Due to the large number of components - in addition to the optical waveguide and the optical ferrules sitting on it - have the above optical connectors on a high assembly cost, which makes this type of optical connectors expensive. Furthermore, such a design is more susceptible to damage and requires a relatively large amount of space, which, for. B. in the cramped conditions in a motor vehicle to an opto-electrical unit in the engine compartment, usually not available. In addition, due to the variety of components such optical connectors are difficult to seal against water.

The DE 20 2005 005 362 U1 discloses an optical connector with two mutually corresponding FAKRA housings, wherein a mechanical connection of the two housings takes place via a mutual contact in the axial direction of the two housings and via a latching connection. An optical coupling of two optical waveguides via two spaced-apart lenses within the optical connector.

The US 4,687,291 A. discloses a watertight coupling for two optical fibers, having a substantially elongated and hollow cylindrical housing, from the two longitudinal ends of each an optical waveguide in the interior of the housing is vorbewegbar, wherein at a respective longitudinal end portion of the respective optical waveguide a driver is set. When the clutch is mounted, a screwable cap which is seated on the respective optical waveguide moves the relevant longitudinal end of the optical waveguide inwards into the housing via the driver. In each case seals a clamped between the housing and the optical waveguide of the cap via a ring and the driver seal the housing relative to the optical waveguide. Within the housing, the two optical waveguides via an inner, central ring and two laterally arranged thereto sealing rings, against which in each case one end of an optical waveguide, provided at a distance from each other.

The JP H01 - 134 314 A discloses a watertight optical port of an optical fiber to a device having an optical port. In this case, the connection has a substantially elongated and hollow-cylindrical receptacle, within which the optical devices of two optical waveguides can be optically coupled. For this purpose, both optical waveguides or both optical devices can be screwed onto the connection by means of a respective cap provided thereon such that an optical device in the receptacle can be moved toward the respective other optical device. A seal of the connection on the outside of the device via a seated on the optical fiber sleeve, a rotatably mounted on the cap cap which is screwed onto a flange provided on the device. Here, the sleeve relative to the optical waveguide and against the cap, and the cap relative to the flange by means of two sealing rings and sealing compound is sealed.

It is an object of the invention to ensure an axial tolerance compensation between two optical devices of the connector in an optical connector. Furthermore, it is an object of the invention to provide an improved optical connector, which in particular has a simple, robust and water-tight or moisture-tight construction and requires little space.

The object of the invention is achieved with an optical connector according to claim 1.

The object of the invention is achieved by means of an optical connector and a corresponding optical jack (optical connector), wherein an optical device of the plug, in particular an optical ferrule of an optical waveguide, with a mechanical bias against a corresponding optical device of the socket, in particular a diode , is pressed. This mechanical preload realizes a tolerance compensation for the two optical devices, so that they are in close contact with each other with mutual contact. The mechanical bias results according to the invention from a locking device, which is preferably provided on the optical connector and is supported on or in a locking device of the socket and on an optical waveguide seal. Preferably, in this case, the locking device is designed as a locking bracket. In the assembled state of the locking bracket surrounds the socket at least partially and provides from the mechanical locking between the plug and socket and the compressed optical waveguide seal a spring force for the optical device preferably the plug available.

As a result, according to the invention, a spring force for the plug housing, and thus also an axial tolerance compensation with respect to the optical axis for the two optical devices of plug and socket, are provided directly by the locking device. As a result, in comparison with the prior art, a large number of components are saved, which makes the plug according to the invention robust in a small installation space volume. Furthermore, the plug according to the invention is cheaper to produce than in the prior art, since apart from the optical fiber seal only two components, namely the connector housing and the locking bracket, are necessary to the optical device or the optical ferrule with bias to another optical device, eg , As the diode of the jack, and thus provide the tolerance compensation.

Preferably, a portion of the plug housing, z. As a protruding into the connector housing projection in the axial direction of the plug directly to the optical ferrule of the plug, whereby the necessary for the tolerance compensation bias is generated by the locking bracket and transmitted via the connector housing. Here, the free end of the plug in the mated state with the jack is preferably added with clearance within the socket, so when plugging the plug with the socket, in the axial direction at first only one time the contact of the optical ferrule of the plug with the corresponding other optical unit in the socket takes place. Preferably, this may be - in addition to the lock itself - the only axial face contact. In another embodiment of the invention, the optical ferrule may also be axially biased slidably provided in the plug, so that the free end of the plug housing is vorbewegbar up to a stop in the socket, and the optical device of the plug with the optical device of the socket in mechanical positive contact is.

The outer diameter configuration of the plug is adapted to the inner diameter configuration of the socket such that preferably only properly oriented insertion of the plug into the socket is possible, and the plug is received in the socket without or with virtually no radial play in the socket. For a correctly oriented insertion Kodierausnehmungen or corresponding Kodiervorsprünge may be provided in the plug or in the socket. These embodiments allow a planar biased seating of the optical ferrule of the plug to the diode of the socket so that an optical transition between these two optical devices is as good as possible. Furthermore, this is, z. As in a flying clutch, and the lateral clearance and an angular offset between the fiber end portions of the optical waveguides minimized.

In a preferred embodiment of the invention, the locking clip is materially integral and provided on the connector housing at one of the optical end sleeve opposite end. In the assembled state of the connector, the locking bracket is supported on the latching device of the socket from such that a bias voltage from the optical waveguide seal for the optical ferrule of the plug is provided. In this case, the optical end sleeve of the plug is preferably performed by a trained as Primärverrastung projection in the direction of the optical axis, which imprints the biasing force resulting from the locking connection between the plug and socket and the compressed optical fiber seal, the optical ferrule of the plug. In this embodiment, the plug and the locking bracket - in addition to the optical ferrule and the optical waveguide attached thereto - each formed as a single part, which makes the production and assembly of the optical connector inexpensive.

The locking bracket is formed separately from the connector housing, whereby a water and dustproof optical connector is provided, at least one seal serves as a biasing element for the optical device of the connector. Preferably, the optical waveguide seal is designed as an elastic element which provides a spring force in the axial direction of the optical connector. Further, the locking bracket is provided as a sliding axially movable component on the connector housing, wherein the locking bracket can be supported on the latching device of the socket such that a biasing force generated acts on the optical waveguide preferably on the Primärverrastung of the plug housing on the optical ferrule of the plug. This is preferably located on an outer circumference of the plug housing a second seal which seals the plug housing relative to the socket. As a result, the optical waveguide and the connector housing is sealed against penetrating water, dust and other media.

According to the invention, it is possible to provide with a two-part plug and two seals a sealed against harmful media optical connector with mechanical tolerance compensation. This is also compact in its design and robust. Furthermore, cost-effective production and production is possible due to the small number of parts.

Preferably, the optical plug according to the invention in addition to the Primärverrastung, a Sekundärverrastung for the optical ferrule, wherein the Sekundärverrastung preferably ansitzt on a trained on the optical ferrule shoulder. The Sekundärverrastung is preferably pressed from the outside into the housing of the plug. The primary latching is similar to the secondary latching on the optical ferrule. For this purpose, the optical end sleeve preferably has two axially offset shoulders, which preferably completely revolve.

It is of course possible, instead of a diode in the socket to provide an optical ferrule or ferrule and so plug and socket z. B. to design as a flying clutch. In addition, it is possible to provide the locking bracket on the socket and the locking device according to the plug.

Further embodiments of the invention will become apparent from the remaining dependent claims.

The invention will be explained in more detail below with reference to embodiments with reference to the accompanying drawings. In the drawing show:

• 1a a first, not claimed in this document variant of an optical connector with a protective cap;
• 1b the plug off 1a when mated with an optical jack;
• 1c Socket and plug in the assembled state;
• 2 an exploded view of the plug with protective cap;
• 3 a partially cutaway perspective view of the plugged into the socket connector according to the first variant;
• 4 a second, inventive variant of the connector, which represents a mating of a plug according to the invention with a socket;
• 5a an exploded view of the plug 4 ;
• 5b inserting an optical ferrule into the plug 4 ; and
• 6 a partially cutaway perspective view of the plugged into the socket connector according to the second variant of the invention.

In the following, the invention will be described with reference to a unidirectional optical coupling for an optical waveguide, which can be coupled via a diode to an electrical circuit board. However, the invention should not be limited to such unidirectional couplings, but include bi-directional and multidirectional couplings for optical fibers, which are not only suitable for connection to an electrical circuit board, but should generally relate to optical connectors. Wherever a tolerance compensation in the direction of the optical axis of the optical connector is necessary, the invention is applicable.

The 1a to 3 show a first variant of an optical connector 300 comprising a socket 200 and one to the jack 200 corresponding plug 100 , The plug 100 is in this case by means of a Kodiervorsprungs or Kodierausnehmung only in a correctly oriented position in the socket 200 insertable, which has a Kodierausnehmung or a Kodiervorsprung accordingly. In the illustrated variant, the substantially hollow cylindrical plug 100 one below (for example, in relation to the 1b) essentially planar configuration, which acts as a coding projection in a correspondingly shaped coding recess in the socket 200 intervenes.

The 1a shows the plug 100 in a delivery state (but without a fiber optic cable connected 132 (see this 2 or 4 )). For this purpose, a connector housing 110 of the plug 100 equipped with a (dust) protective cap 120, on the one hand, the connector housing 110 protects against damage and on the other hand a free end of an optical device 130 of the plug 100 preserved from contamination. The dust cap 120 is preferably between a part of the housing 110 of the plug 100 circumferential locking bracket 112 and the actual connector housing 110 supported.

The 1b shows the plug 100 without protective cap 120 before mating with the socket 200 that prefers on a circuit board 400 arranged and preferred as a collar 200 is formed, which is a diode 230 (S. 3 ) having. This diode 230 converts optical signals of the optical waveguide 132 into electrical signals for the printed circuit board 400 around.

In the 2 is the structure of the plug 100 clearly visible. The plug 100 points to its housing 110 , Preferably integrally formed, the locking bracket 112 on, at least partially around the cylindrical connector housing 110 circulates. The locking bracket 112 in this case preferably covers at least an angle of 180 ° on the connector housing 110 from. However, this angle is preferably about 270 ° (s. 3 ). On the side of the locking bracket 112 , the preferred at the optical waveguide end of the plug 100 is provided, from behind into the connector housing 110 an optical device 130 , z. B. an optical ferrule 130 or a ferrule 130 used.

The optical ferrule 130 latched within the housing 110 at least one Primärverrastung 114 (S. 3 ), so the optical ferrule 130 slipping out in at least one axial direction A is hindered. The primary catch 114 is preferably at least one in the connector housing 110 protruding projection 114 who is on one shoulder 131 the optical ferrule 130 supported. Preferably, there is the Primärverrastung 114 however, at least two corresponding abutment surfaces. The lead 114 supports the optical ferrule 130 of the plug 100 on a stop surface in the plug 100 from. Furthermore, a secondary latching is preferred 140 for the optical ferrule 130 in the connector housing 110 provided, with the Sekundärverrastung 140 , from the outside via passage recesses in a wall of the plug housing 110 , in the case 110 is vorbewegbar and latched. In this case, the secondary locking locked 140 the optical ferrule 130 in the case 110 also on one shoulder 131 the optical ferrule 130 , By means of the two locks 114 . 140 is ensured that the optical ferrule 130 oriented correctly in all three spatial directions, firm and secure in the connector housing 110 is provided. Thus further, the inward into the connector housing 110 protruding primary catch 114 a sufficiently inward springy projection 114 has (for the insertion of the optical ferrule 130 ), this is on its long sides to the wall of the plug housing 110 spaced apart. Preferably, this elongated hook, only at one longitudinal end opposite the projection 114 , with the connector housing 110 preferably materially connected in one piece.

The plug 100 locked by means of the locking bracket 112 on a latching device 212 the socket 200 , This locked state is in the 1c and 3 to recognize. The locking bracket 112 is for this purpose preferably in one piece with the connector housing 110 connected to it in the axial direction A of the optical connector 100 is resiliently movable back and forth. This is with the double arrow in 2 clarified. Ie. the upper portion of the locking bracket 112 is at least in the axial direction A reciprocally movable, wherein a rest position of the locking bracket 112 on the loose plug 100 is chosen such that the latter in the assembled state with the socket 200 , a bias of the optical ferrule 130 over at least the primary catch 114 of the connector housing 110 on the diode 230 the socket 200 provides. As a result, an axial tolerance compensation for the optical ferrule 130 of the plug 100 realized. Of particular advantage here is that only the plug component, the biasing force for the optical ferrule 130 provides, and thus for fixing the optical ferrule 130 and a tolerance compensation for this only a single component is necessary. So that the optical ferrule 130 with bias on the diode 230 is present, is in the locked state, a free end 116 of the connector housing 110 preferably with air in the socket housing 210 added.

The primary catch 114 and secondary locking 140 can the optical ferrule 130 but also with a certain play in the axial direction A inside the connector housing 110 to store. However, if the plug is located 100 in the locked state with the socket 200 , so are primary 114 and / or secondary latching 140 so on the appropriate shoulder 131 the optical ferrule 130 fitting that at least one of the two shoulders 131 the biasing force from the locking bracket 112 on the optical ferrule 130 provides.

In the illustrated embodiment, there is the locking of the plug 100 with the socket 200 from one on the socket housing 210 trained above latch hooks 212 , which preferably has a ramp for the locking bracket 112 having. The locking bracket 112 is formed as a curved cuboid, with a shoulder on a vertical end face of the latching hook 112 can sit down. However, this can also be executed kinematically reversed, with a latching hook on the locking bracket 112 is provided vertically projecting downwards and accordingly in the socket housing 210 a locking device provided as a latching device 212 is provided. To postpone the locking clip 112 on the socket housing 210 To facilitate this can also be provided with a ramp (not shown). To loosen the optical connector 300 with the help of lateral actuating surfaces 115 (see below) is the socket housing 210 in the plug-in direction of the plug 100 except vertical sloping downwards. This further facilitates centered insertion of the plug 100 in the socket 200 ,

A gap between the locking bracket 112 and the connector housing 110 is preferably formed U-shaped, wherein the curved portion takes place the lock and the two straight sections enough clearance to the socket housing 210 (in the assembled state of the optical connector 300 ) or to the connector housing 110 is present, whereby by means of a radial compression of these two sections, on the opposite actuating surfaces 115 , the curved portion of the locking bracket 112 moved vertically upward so that the locking of the optical connector 300 is solvable again. After removing the plug 100 from the socket 200 should the protective cap 120 back on the plug 100 be plugged.

In an upper area is the locking bar 112 preferably excluded at the rear, so that in the assembled state of the optical connector 300 a rear end of the plug 100 with a front free end 216 of the socket housing 210 in alignment. So that the protective cap 120 also on the connector housing 110 locked, this is also preferred with a locking device 122 provided, the latching device 212 the socket 200 is modeled. Furthermore, the connector housing 110 one preferably completely at the free end 116 encircling beveled slip on, which makes it possible to remove the plug 100 just in the socket 200 plug in and center in this.

The 4 to 6 show a second, preferably water and dustproof, variant of the optical connector according to the invention 300 , The socket 200 or the socket housing 210 or the collar 210 are hereby made similar to the first variant, wherein preferably within the socket 200 a stepped portion exists as the sealing surface within the female housing 210 acts. In contrast to the connector housing 110 according to the first variant, is the locking bracket 112 separately from the connector housing 110 provided and on this in the axial direction A movably arranged. Otherwise, that portion of the plug housing is preferred 110 , which is the optical ferrule 130 receives as well as the connector housing 110 executed in the first variant. The same applies to the optical ferrule 130 of the plug 100 ,

The structure of the plug 100 is best in the 5a to 6 to recognize, in or on the plug 100 two seals 150 . 152 are provided. The as an optical fiber seal 150 trained seal 150 is inside the plug housing 110 , in the axial direction A between a rear portion of the locking bracket 112 and the housing 110 , in the housing 110 provided inside, wherein the rear portion of the locking bracket 112 in the case 110 engages and the optical fiber seal 150 in the housing determines. The rear section of the locking bracket 112 For this purpose, it is preferably equipped with a circular ring cross section, so that a continuous biasing force impingement (see below) on the optical waveguide seal 150 can take place. The fiber optic seal 150 seals the fiber optic cable 132 opposite the connector housing 110 from. Furthermore, on the case 110 a second, as a housing seal 152 trained, seal 152 provided, which the connector housing 110 opposite the socket housing 210 , in the assembled state of the optical connector 300 , inside in the socket housing 210 seals. The housing seal 152 is hereby preferably by means of Sekundärverrastung 140 the optical ferrule 130 held in place, which is in the 5b and 6 can be seen.

The locking bracket 112 sits with a rear (in relation to the 5b and 6 ) hollow cylindrical portion on an outer cylindrical portion of the plug housing 110 , and is by means of one on the housing 110 provided projection 118 and one on the locking bracket 112 provided shoulder on a slide down from the connector housing 110 secured. Forward, the locking bracket 112 also not from the connector housing 110 slide down, as the hollow cylindrical rear end of the plug housing 110 in an annular cavity within the locking bracket 112 is included. The locking bracket 112 has at least one bracket 112 ' but prefers two diametrically opposed stirrups 112 ' , on, by means of his rear shoulder on the preferred as latching hooks 212 trained locking device 212 the socket 200 in the assembled state of the optical connector 300 locked.

According to the invention, the elastic optical waveguide seal 150 a biasing force for the connector housing 110 available, preferred over the Primärverrastung 114 of the housing 110 the optical ferrule 130 of the plug 100 biased against the optical device 230 the socket 200 suppressed. As a result, in turn, a firm sitting of the optical device 130 of the plug 100 at the optical device 230 the socket 200 realized. According to the invention, it is not necessary, the bracket 112 ' of the locking bracket 112 provide resilient, since the optical fiber seal 150 is formed correspondingly elastic. When plugging in the plug 100 in the socket 200 slide the temples 112 ' over the locking hooks 212 the socket 200 , wherein before reaching the locking position of the locking bracket 112 on the socket 200 , the fiber optic seal 150 in the axial direction A is compressed, causing the connector housing 110 the optical device 130 in the axial direction A advanced. When plugged in, the fiber optic cable seals 150 in the axial direction A always an axial force on the housing 110 out. A release of the lock takes place in turn by pressing the actuating surfaces against each other 115 instead, taking the hanger 112 ' from the latching hook 212 the socket 200 Move away vertically.

In the 6 is the at the optical ferrule 130 assembled optical fibers 132 clearly visible. To the very front through the optical ferrule 130 through, a fiber extends 134 of the optical fiber 132 , which is responsible for the transport of light waves. Behind it is the fiber optic cable 132 with a jacket or sheath in the optical ferrule 130 received mechanically locked.

In addition, it is possible the optical connector 100 the first variant, with the fiber optic seal 150 and the housing seal 152 to equip the second variant of the invention. In this case, however, then the bias for the optical device 130 of the plug 100 no longer of the fiber optic seal 150 generates or mediates, but as in the first variant of the invention on the locking bracket 112 and the connector housing 110 It can also be used for the optical fiber seal 150 and the housing seal 152 be necessary, a locking collar o. Ä. In and / or on the connector housing 100 provided.

LIST OF REFERENCE NUMBERS

100

plug

110

Housing, plug housing

112

locking clip

112 '

Bracket (only 2nd variant)

113

Shoulder (only 2nd variant)

114

Primary locking of optical ferrule, tab

115

actuating surface

116

(free) end of the connector housing

118

Advantage (only 2nd variant)

120

(Dust) protective cap

122

Locking device, preferably latching hooks

130

optical device, optical ferrule, ferrule

131

shoulder

132

optical fiber

134

fiber

140

Secondary locking of the optical ferrule

150

Optical fiber seal

152

housing seal

200

Bush, collar

210

Housing, socket housing, collar housing

212

Locking device, preferably latching hooks

216

(free) end of the socket housing

230

optical device, diode

300

optical connector, (flying coupling)

400

circuit board

A

Axial direction of the optical connector 300 , the plug 100 and the socket 200 ; optical axis

Claims (14)

Optical joint (300) with axial tolerance compensation for an optical connection, comprising at least one socket (200) having a housing (210), an optical device (230) and a latching device (212), and at least one to the socket (200) corresponding connector (100), which comprises a housing (110), an optical device (130), an outer latching bracket (112) at least partially encircling the housing (110) and an elastic optical fiber seal (150) by means of which in the axial direction (A) the optical connector (300) is a spring force is available, wherein the locking bracket (112) is formed as a separate part on the housing (110) of the plug (100), on the housing (110) is arranged to be movable in the axial direction (A) and on the latching device (212) is supportable, that the optical Means (130) via the elastic optical fiber seal (150) from the housing (110) directly against the optical device (230) can be pressed, and by the interaction of the locking bracket (112) with the elastic optical fiber seal (150) and the latching device (212) in the mated state of the plug (100) with the socket (200), the optical device (130) with an axial tolerance compensation realizing, mechanical bias of the elastic optical fiber seal (150) in the axial direction (A), on the optical device (230) is applied. Optical connector (300) according to Claim 1 , wherein the optical device (130) of the plug (100) is fixedly arranged in the housing (110), and in the assembled state of the optical connector (300), the two housings (210, 110) are inserted into one another, wherein a free end (116 ) of the housing (110) of the plug (100) in the housing (210) of the socket (200) is received with a play in the axial direction (A). Optical connector (300) according to Claim 1 or 2 wherein the elastic optical fiber seal (150) is formed as an elastic member providing a spring force in the axial direction (A) of the optical connector (300). Optical connector (300) according to one of Claims 1 to 3 , wherein in the assembled state of the optical connector (300), the housing (110) of the plug (100) by means of a housing seal (152) in the housing (210) of the socket (200) is received fluid-tight. Optical connector (300) according to one of Claims 1 to 4 wherein the housing (110) has a primary catch (114) for the optical device (130) such that the optical device (130) is prevented from slipping out in at least one axial direction. Optical connector (300) according to Claim 5 wherein the primary latch (114) is formed as a projection (114) projecting inwardly of the housing (110). Optical connector (300) according to one of Claims 1 to 6 wherein between the housing (110) and the optical device (130) a secondary latch (140) is arranged, which locks the optical device (130) in the axial direction (A) of the optical connector (300) in the housing (110). Optical connector (300) according to Claim 7 , wherein the Sekundärverrastung (140) from the outside into the housing (110) can be plugged. Optical connector (300) according to one of Claims 1 to 8th in which the optical device (130) of the plug (100) is an optical end sleeve (130) of an optical waveguide (132). Optical connector (300) according to one of Claims 1 to 9 wherein the bushing (200) is formed as a collar (200) which is arranged on a printed circuit board (400). Optical connector (300) according to one of Claims 1 to 10 wherein the optical device (230) of the socket (200) is a diode (230). Optical connector (300) according to one of Claims 1 to 11 , wherein by means of the Primärverrastung (114) and the Sekundärverrastung (140), the optical device (130) fixedly and securely in the housing (110) is arranged. Optical connector (300) according to one of Claims 1 to 11 , wherein the latching device (212) on the plug (100) and the locking bracket (112) on the socket (200) is arranged. Use of an optical connector (300) according to one of Claims 1 to 13 in a video link system, camera system or optical coupling.

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