JP6337048B2 - Fiber optic joint, fiber optic adapter, and fiber optic connector - Google Patents

Description

  The present invention relates to the field of data communication equipment, and more particularly to an optical fiber joint, an optical fiber adapter, and an optical fiber connector.

  In optical fiber communication systems, optical fiber connectors are configured for connections between optical cables, optical cables and optical-electrical components, and optical-electrical components. The fiber optic connector accurately interconnects the end faces of the two optical fibers that need to be connected so that the optical energy output by the transmit optical fiber can be maximally coupled to the receive optical fiber.

  Fusion splicing technology is commonly used during the placement of fiber to the home (FTTH) network lead-in cables. That is, the optical fiber terminal is assigned to the fiber distribution box, the optical fiber terminal and the incoming optical cable are connected using the optical fiber fusion splicer in the optical fiber distribution box, and the incoming optical cable is laid in each house. A field splice connection is also required at the other end of the retractable optical cable so that the retractable optical cable is connected to the terminal box of each home user. The above-mentioned fusion splicing technique requires a dedicated optical fiber fusion splicing apparatus, and high technical demands are demanded from workers. Furthermore, the work process is cumbersome and inconvenient.

  In view of this, an embodiment of the present invention provides a fiber optic joint, a fiber optic adapter, and a fiber optic connector that solve the problems in the prior art that are plug and play and that the on-site fusion splicing is cumbersome To do.

  According to a first aspect, embodiments of the present invention provide an optical fiber joint (100), the optical fiber joint (110) and an inner sleeve member (140) having a cavity therein, the optical cable ( 110) is held in the cavity, one end of the inner sleeve member (140) is fixed in the optical cable (110), and the sleeve (180) is disposed at the other end. An inner sleeve member and an outer sleeve member (130), wherein the outer sleeve member (140) is sleeved on the outside of the inner sleeve member (140), and the outer sleeve member (140) is a sleeve (180) An outer sleeve member rotatable about an axis about the sleeve (1) of the inner sleeve member (140) 0) projects at least partially out of the outer sleeve member (130), and the tail end of the sleeve (180) protruding out of the outer sleeve member (130) has an opening, and the sleeve (180 ) Forms a C-shaped cross section.

  In a first possible implementation of the first aspect, the C-shaped tail end of the sleeve (180) is configured to connect to the C-shaped slot (2012) of the fiber optic adapter (200) that fits the fiber optic joint (100). Is done.

  In a second possible implementation of the first aspect, the opening of the sleeve (180) is configured to connect to a positioning key (2014) of the fiber optic adapter (200) that fits into the fiber optic joint (100).

  In a third possible implementation of the first aspect, the sleeve (180) is configured to connect to a slot (2012) of a fiber optic adapter (200) that fits into a fiber optic joint (100), and the sleeve (180) The C-shaped cross section at the tail end matches the C-shaped cross section of the slot (2012) of the optical fiber adapter (200).

  In a fourth possible implementation of the first aspect, the opening of the sleeve (180) is horn shaped.

  In a fifth possible implementation of the first aspect, the opening angle of the horn shaped opening of the sleeve (180) is not less than 10 degrees and not more than 30 degrees.

  In a sixth possible implementation of the first aspect, the opening angle of the horn-shaped opening of the sleeve (180) is 15 degrees or 22.5 degrees.

  According to a second aspect, an optical fiber adapter (200) is provided. A socket (201) is disposed at one end of the optical fiber adapter (200), a cavity (2011) and a slot (2012) configured to hold an optical fiber are disposed in the socket (201), and the cavity (2011) is Located in the middle of the socket (201) and the slot (2012) surrounds the cavity (2011), and a positioning key (2014) is disposed in the socket (201) and the slot (2012) is C-shaped. A cross section is formed.

  In a first possible implementation of the second aspect, the slot (2012) having a C-shaped cross-section holds the C-shaped tail end of the sleeve of the fiber optic joint (100) that fits into the fiber optic adapter (200). Configured.

  In a second possible implementation of the second aspect, the positioning key (2014) is configured to connect to the opening of the sleeve of the fiber optic joint (100) that fits into the fiber optic adapter (200).

  In a third possible implementation of the second aspect, the width of the positioning key (2014) is equal to the width of the opening of the fiber optic joint (100).

  According to a third aspect, an optical fiber connector (10) is provided that includes an optical fiber joint (100) and an optical fiber adapter (200). The optical fiber joint (100) is an optical cable (110) and an inner sleeve member (140) having a cavity therein, and an optical fiber extending outside the optical cable (110) is held in the cavity, and the inner sleeve member ( 140) an inner sleeve member (140) and an outer sleeve member (130), one end of which is fixed to the optical cable (110) and the sleeve (180) is disposed at the other end. 130) includes an outer sleeve member (130) that is sleeved on the outer side of the inner sleeve member (140), and the outer sleeve member (140) is rotatable about an axis about the sleeve. The sleeve of the sleeve member (140) protrudes at least partially out of the outer sleeve member (130) and the tail end of the sleeve. So as to form a C-shaped cross-section, the tail end of the sleeve which projects out of the outer sleeve member (130) has an opening.

  A socket (201) is disposed at one end of the optical fiber adapter (200), and a cavity (2011) configured to receive an optical fiber and a slot (2012) are disposed in the socket (201) and the cavity (2011). ) Is located in the middle of the socket (201), and the slot (2012) surrounds the cavity (2011), and the positioning key (2014) is disposed in the socket (201) and the slot (2012). ) Forms a C-shaped cross section.

  In a first possible implementation of the third aspect, the inner wall of the outer sleeve member (130) of the fiber optic joint (100) has at least one protrusion (1304).

  In a second possible implementation of the third aspect, at least one sliding slot (2015) is located on the outer surface of the socket (201) of the fiber optic adapter (200).

  In a third possible implementation of the third aspect, the fiber optic joint (100) is inserted into the fiber optic adapter (200) and the protrusion (1304) is connected to the sliding slot (2015).

  Based on the foregoing technical solution, the fiber optic connector provided by the embodiments of the present invention is seamlessly connected to the C-shaped slot of the fiber optic adapter using a sleeve having a C-shaped opening of the fiber optic joint. In this way, blind insertion of the fiber optic joint is performed and operation becomes easier, thereby performing plug and play of the fiber optic connector.

  BRIEF DESCRIPTION OF THE DRAWINGS To illustrate the technical solutions in the embodiments of the present invention more clearly, the following briefly describes the accompanying drawings required for describing the embodiments or the prior art. Apparently, the accompanying drawings in the following description show only some embodiments of the present invention, and those skilled in the art will still be able to extract other drawings from these accompanying drawings.

1 is a structure of a communication network applied according to an embodiment of the present invention. 1 is a schematic structural diagram of an optical fiber connector according to an embodiment of the present invention. 1 is a schematic structural diagram of an optical fiber connector according to an embodiment of the present invention. 1 is a schematic structural diagram of an optical fiber joint according to an embodiment of the present invention. 1 is an exploded view of an optical fiber joint according to an embodiment of the present invention. 1 is an assembly diagram of an optical fiber joint according to an embodiment of the present invention. 6 is a front view of an outer sleeve member according to an embodiment of the present invention. FIG. FIG. 6 is a front view of an outer sleeve member according to another embodiment of the present invention. 1 is a schematic structural diagram of an optical fiber adapter according to an embodiment of the present invention. 1 is an exploded view of an optical fiber adapter according to an embodiment of the present invention. FIG. It is the schematic of the opening angle of the sleeve of the optical fiber joint by embodiment of this invention.

  For ease of understanding, the following clearly describes the technical solutions in the embodiments of the present invention with reference to the accompanying drawings in the embodiments of the present invention. Apparently, the described embodiments are a part rather than all of the embodiments of the present invention. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without inventiveness fall within the protection scope of the present invention.

  Figure 1 shows a part of an FTTx optical network, where FTTx is FTTH (Fiber To The Home), FTTC (Fiber To The Curb), or FTTP (Fiber To The Premises). Toza Premises), or FTTN (Fiber To The Node or Neighborhood), or FTTO (fiber To The Office), or FTTSA (Fiber To The Service area) Can do. Using an FTTH network as an example, the FTTH is viewed from the downstream of the central office (CO) as follows: supply link 1, first 1: N splitter 2, distribution link 3, second 1: N splitter 4 , And at least one branch link 5. In the present invention, an optical fiber connector applicable to an outdoor environment can be applied to the branch link 5. The present invention uses an FTTx type network structure as an example, but other network structures can also be used.

  FIG. 2a shows an optical fiber connector 10 of the present invention. As shown in FIG. 2 a, the optical fiber connector includes an optical fiber joint 100, an optical fiber joint 300, and an optical fiber adapter 200. The optical fiber joint 100 is connected to the optical fiber joint 300 using an optical fiber adapter 200, and realizes internal optical fiber interconnection.

  FIG. 2 b is a schematic view of the optical fiber joint 100. As shown in FIG. 2 b, the optical fiber joint 100 includes an optical fiber 110, an inner sleeve member 140, and an outer sleeve member 130 when viewed from the external structure. The inner sleeve member 140 has a cavity inside, and holds an optical fiber extending outside the optical cable 110 in the cavity. One end of the inner sleeve member 140 is fixed to the optical cable 110, and the sleeve 180 is the other end. Placed in the section. The outer sleeve member 130 is sleeved outside the inner sleeve member 140, and the outer sleeve member 130 is rotatable about an axis about the sleeve 180. The sleeve 180 of the inner sleeve member 140 projects at least partially out of the outer sleeve member 130 and projects out of the outer sleeve member 130 such that the tail end of the sleeve 180 forms a C-shaped cross section. The tail end of the has an opening. A sleeve having a C-shaped opening is seamlessly connected to the C-shaped slot of the fiber optic adapter. In this way, blind insertion of the fiber optic joint is performed and easier to operate, thereby realizing plug and play of the fiber optic connector.

  The sleeve 180 can be a cylindrical sleeve, an elliptical sleeve, or another shaped sleeve. Embodiments of the present invention use a cylindrical sleeve 180 as an example. When viewed from the opposite side of the axial direction of the sleeve 180, the C-shaped opening of the sleeve 180 is a circle or an ellipse having an opening.

  As further shown in FIG. 5 a, the C-shaped tail end of the sleeve 180 is configured to connect to a C-shaped slot 2012 of the optical fiber adapter 200 that fits into the optical fiber joint 100. The opening of the sleeve 180 is configured to connect to the positioning key 2014 of the optical fiber adapter 200 that fits into the optical fiber joint 100. The sleeve is configured to connect to a slot 2012 of a fiber optic adapter 200 that conforms to the fiber optic joint 100, and the C-shaped cross section at the tail end of the sleeve matches the C-shaped cross section of the slot 2012 of the fiber optic adapter 200.

  Furthermore, the opening of the sleeve 180 has a horn shape. The opening angle of the horn-shaped opening of the sleeve 180 is not less than 10 degrees and not more than 30 degrees. The opening angle of the horn-shaped opening of the sleeve 180 is 15 degrees or 22.5 degrees.

  Further, the outer sleeve member 130 is a step-shaped circular tube structure with an inner surface having two protruding lock points 1304 (not shown in FIG. 3a, see 1304 for FIGS. 4 and 5). When connected to the fiber optic adapter 200, the locking point 1304 is fixed in the second sliding slot 2015 (not shown in FIG. 3a, see FIG. 5a) of the adapter part 210, thereby realizing a locking connection. To do. The outer front end of the outer sleeve member 130 has an arrow alignment identification for indicating the connector connection and disconnection state, and the rear end of the outer sleeve member 130 has a symmetrical cutting surface, and There is a vertical shallow groove in the plane to enhance the sense of operation.

  As shown in FIG. 3 a, the optical fiber joint 100 further includes a terminal ferrule 120, an insertion core 150, a rope 160, and a joint dust cap 170.

  A symmetrical second sliding slot 1704 is disposed on the outer surface of the joint dust cap 170, and the joint dust cap 170 is equipped with an O-shaped seal ring 172. The joint dust cap 170 is connected to the main body of the optical fiber joint 100 using a rope 160.

  FIG. 3b is an exploded view of the fiber optic joint, and FIG. 3c is an assembly view of the fiber optic joint. As can be seen in FIGS. 3b and 3c, referring to FIG. 3b from the perspective of the internal structure, the optical fiber joint 100 comprises a ferrule 122, a snap ring 126, an O-shaped seal ring 132, an O-shaped seal ring 136, and an O-shaped seal ring. 172, elastic part 134, and connection part 138. Referring to FIGS. 3 a and 3 b, in this embodiment of the invention, an insertion core 150, a connection piece 138, an elastic piece 134, and an outer sleeve member 130 are sequentially sleeved over the optical cable 110.

  Referring to FIG. 3 c, the insertion core 150 is sleeved on the optical cable 110. In this implementation method, the insertion core 150 is a cylindrical body having a plurality of steps. The optical cable 110 passes through the insertion core 150. The insertion core 150 includes two end portions 150 a and 150 b arranged opposite to each other, and the optical cable 110 is exposed at the end portion 150 b of the insertion core 150 that is away from the connection component 138. The connection component 138 has a sleeve attached to the end 150 a of the insertion core 150. The aramid yarn inside the optical cable 110 is fixed to the connection component 138 using the snap ring 126. The end ferrule 120 can be already made and finally sleeved onto the optical cable, or it can be a molded part of an integral injection method.

  The connecting piece 138 includes two ends 138a and 138b disposed opposite to each other. An end portion 138 a of the connection component 138 is screwed to the end portion 150 b of the insertion core 150. The other end 138 b of the connection component 138 is fixed to the aramid yarn outside the optical cable 110 using the snap ring 126. The end 138a of the connecting piece 138 is sleeved with O-shaped seal rings 132 and 136 for sealing. The end 138a of the connection piece 138 includes a shaft shoulder 138c. The shaft shoulder 138 c is configured to abut against the elastic component 134.

  The elastic part 134 includes two ends 134a and 134b arranged opposite to each other. The end part 134 a of the elastic part 134 abuts against the end part 138 a of the connection part 138 close to the insertion core 150. In this implementation, the elastic part 134 is a spring, and the elastic part 134 has a sleeve on the connection part 138. The end part 134 a of the elastic part 134 abuts against the shaft shoulder part of the connection part 138.

  The outer sleeve member 130 includes two ends 130a and 130b that are disposed opposite to each other. The outer sleeve member 130 is sleeved over the connecting piece 138 and the insertion core 150. The end portion 130 a of the outer sleeve member 130 is slidably connected to the connection component 138 and abuts against the end portion 134 b of the elastic component 134. The elastic component 134 is configured to provide an elastic force against the insertion core 150 for the outer sleeve member 130, thereby preventing a loose connection. A symmetrical lock point 1304 (1304 see FIGS. 4a and 4b) is located on the inner wall of the end 130b of the outer sleeve member 130, and the lock point 1304 is a cylindrical protrusion.

  In this implementation method, the outer sleeve member 130 is a cylindrical body having steps. The end 130a of the outer sleeve member 130 forms an inward flange 130d configured to abut against the end 134b of the elastic component 134. The elastic part 134 is clamped between the flange 130d and the shaft shoulder 138c. Two opposing locking points 1304 are disposed on the inner wall of the end 130b of the outer sleeve member 130, and the locking point 1304 is a cylindrical protrusion. Of course, in other implementations, a plurality of locking points 1304 can be disposed around the outer sleeve member 130.

  The outer surface of the other end portion 130b of the outer sleeve member 130 has an alignment identification of an arrow indicating the connection and disconnection state of the optical fiber connector 10. The outer surface of the outer sleeve member 130 has a symmetrical cut surface, and there is a vertical shallow groove in the plane to enhance the operational feeling.

  The inner sleeve member 140 extends along the axial direction of the insertion core 150, and the end 150 b of the insertion core 150 far from the connection component 138 is held in the inner sleeve member 140. In this embodiment, one end portion of the inner sleeve member 140 is fixed by a snap ring, and the snap ring is provided with a sleeve at the end portion 150 b of the insertion core 150. The inner sleeve member 140 has a sleeve protruding forward, and the sleeve is C-shaped and protrudes out of the end surface of the ceramic insertion core of the insertion core 150 to realize a protection function for the insertion core. Prevents contamination of the end face of the insert core due to contact with other parts during the insertion and removal operation, or protects the insert core from damage due to dropping. When viewed in the longitudinal direction, the sleeve has a horn-shaped opening, and the horn-shaped opening is located on the positioning key 2014 (see FIG. 5 a) of the optical fiber adapter 200 when the optical fiber joint 100 is inserted into the optical fiber adapter 200. It is configured to be fitted so that the fiber optic joint 100 is accurately aligned with the fiber optic adapter 200.

  Furthermore, the opening angle of the horn-shaped opening is not less than 10 degrees and not more than 30 degrees. As shown in FIG. 6, the opening angle is an angle formed between the axial direction of the sleeve and the edge direction of the horn-shaped opening, and is particularly 10 degrees, 15 degrees, 22.5 degrees, or 30 degrees. be able to.

  The end portion 130 b of the outer sleeve member 130 is fixed and sealed to the optical cable 110 using the ferrule 122.

  The end ferrule 120 is sleeved to the ferrule 122 and secured with a snap ring 126, thereby enhancing the tensile strength and sealing performance of the fiber optic joint 100. The end ferrule 120 can be already molded and finally the optical cable can be sleeved, or it can be cast in a single injection method.

  The optical fiber joint 100 includes a joint dustproof cap 170. Referring to FIG. 3 a, the joint dustproof dust 170 is connected to the optical fiber joint 100 using a rope 160. The joint that holds the cavity is disposed at one end of the joint dust cap 170, the joint that holds the cavity extends in the axial direction along the joint dust cap 170, and the joint that holds the cavity is the insertion core 150. And holds the inner sleeve member 140. The joint dust cap 170 has an O-shaped seal ring 172.

  In FIG. 3a, at least one first sliding slot 1704 is disposed on the outer periphery of the joint dust cap 170 and the number of sliding slots 1704 is the number of lock points 1304 (see FIGS. 4a and 4b for lock points 1304). Equal to a number. The sliding slot 1704 cooperates with the lock point 1304 of the outer sleeve member 130, and the sliding slot 1704 has a spiral shape. The sliding slot 1704 extends from one end of the joint dust cap 170 to the outer periphery of the joint dust cap 170. And the extended tail end of the sliding slot 1704 is secured to the lock point 1304. In this implementation, the extended tail end of the sliding slot 1704 is in the form of an arc that conforms to the shape of the lock point 1304. The outer surface of the joint dust cap 170 has an arrow identification and “0” and “1” identification. When the optical fiber joint 100 is inserted into the joint dustproof cap 170, the arrow identification of the outer sleeve member 130 is aligned with the arrow identification of the joint dustproof cap 170. When the joint dust cap 170 is rotated in the “0” direction, the optical fiber joint 100 is locked, and when the joint dust cap 170 is rotated in the “1” direction, the optical fiber joint 100 is in the released state. Become. A double lock method is used, thereby ensuring long-term, reliable optical performance of the fiber optic connector.

  When the joint dust cap 170 is fixed to the optical fiber joint 100, the insertion core 150 and the inner sleeve member 140 are inserted into the holding cavity. The lock point 1304 of the optical fiber joint 100 slides into the sliding slot 1704 of the joint dust cap 170 and the joint dust cap 170 is rotated from the direction “1” to the direction “0”, and as a result, the lock point 1304. The sliding end of the sliding slot 1704 slides, thereby locking. By the above operation, the joint dustproof cap 170 is fixed to the optical fiber joint 100.

  4a and 4b are front views of the fiber optic joint 100, showing the internal fastener unlocking structure of the fiber optic joint 100. FIG. FIG. 4a shows the internal unlocking structure when the insertion core 150 does not have snap-lock vanes. The left side (a) of FIG. 4 a shows the initial state of the internal fastener of the optical fiber joint 100, and the right side (b) of FIG. 4 a shows the locked state of the internal fastener of the optical fiber joint 100. FIG. 4b shows the internal unlocking structure when the insertion core 150 has snap-lock vanes. The left side (a) of FIG. 4b shows the initial state of the internal fastener of the optical fiber joint 100, and the right side (b) of FIG. 4b shows the locked state of the internal fastener of the optical fiber joint 100.

  As shown in FIG. 4 b, the inner surface of the outer sleeve member 130 has an inclined boss 1302. When the optical fiber joint 100 and the optical fiber adapter 200 are connected and locked, the inclined boss 1302 bypasses the snap-lock blade 1502 of the insertion core 150, in which case the snap-lock blade 1502 is connected to the socket 201 (see FIG. 5a). ) And is thus connected and locked.

  In this embodiment, it should be noted that an insert core 150 without snap-lock blades can also be adapted, in which case the inner surface of the outer sleeve member 130 does not have a corresponding inclined boss. .

  In addition, two symmetrical locking points 1304 on the inner surface of the outer sleeve member 130 are secured to two symmetrical second sliding slots 2015 on the outer surface of the socket 201 (see FIG. 5a), thereby providing a double lock and connection. . When it is necessary to remove the optical fiber joint 100 from the optical fiber adapter 200, the outer sleeve member 130 changes from the state shown in the left side (a) of FIG. 4b to the state shown in the right side (b) of FIG. 4b. Turned. In this case, the snap-lock blade 1502 of the insertion core 150 is compressed by the inclined boss 1302 of the outer sleeve member 130, thereby realizing tightening and unlocking. Meanwhile, the two symmetric lock points 1304 on the inner surface of the outer sleeve member 130 are also rotated and released from the two symmetric second sliding slots 2015 on the outer surface of the socket 201, in which case the fiber optic joint 100 is connected to the fiber optic adapter 200. Can be removed from.

  Furthermore, in this embodiment, the outer sleeve member 130 can be rotated 45 degrees to perform the connector locking and unlocking process. In order to limit the rotation angle of the outer sleeve member 130, a limiting post 1504 is disposed on the insertion core 150, and left and right limiting stages 1306 are designed on the outer sleeve member 130. When the connector is in the connected and locked state as shown on the left side (a) of FIG. 4b, the limiting post 1504 is limited by the left limiting stage 1306 and cannot be rotated further, and the connector is on the right side of FIG. 4b. When in the released state as shown in (b), the restriction column 1504 is restricted by the right restriction stage 1306 and cannot be further rotated.

  FIG. 5 a is a schematic structural diagram of the optical fiber adapter 200. FIG. 5 b is an exploded view of the optical fiber adapter 200. As shown in FIGS. 5 a and 5 b, the socket 201 is disposed at one end of the optical fiber adapter 200.

  Further, the socket 202 can be further disposed at the other end of the optical fiber adapter 200. The two sockets 201 and 202 and the ceramic ferrule 212 located in the center of the adapter can be welded together using ultrasound.

  The socket 201 has a cavity 2011 and a slot 2012, the cavity 2011 is located in the middle of the socket 201, and the cavity 2011 and the slot 2012 extend along the socket 201 in the axial direction. The slot 2012 surrounds the cavity 2011. The cavity 2011 cooperates with the insertion core 150, the slot 2012 cooperates with the inner sleeve member 140, and the positioning key 2014 is disposed in the slot 2012. The positioning key 2014 is a strip-shaped protrusion extending in the axial direction along the socket 201, and the slot 2012 forms a C-shaped cross section and seamlessly connects with a sleeve having a C-shaped opening in the optical fiber joint. In this way, blind insertion of the optical fiber joint can be carried out, which makes operation easier, thereby realizing plug and play of the optical fiber connector.

  When viewed from the opposite side to the axial direction of the socket 201, the C-shaped slot 2012 is a circle or an ellipse having an opening. When the fiber optic joint 100 is inserted into the fiber optic adapter 200, the C-shaped inner sleeve member cooperates with the positioning key 2014 and is inserted into the slot 2012. In this embodiment, the sockets 201 and 202 are cylindrical. The cavity 210 is a square cavity or a circular cavity. The slot 2012 is a C-shaped slot.

  A slot 2012 having a C-shaped cross section is configured to hold the C-shaped tail end of the sleeve 180 of the fiber optic joint 100 that fits into the fiber optic adapter 200. The positioning key 2014 is configured to connect to the opening of the sleeve of the optical fiber joint 100 that is compatible with the optical fiber adapter 200. The width of the positioning key 2014 is equal to the width of the opening of the sleeve 180 of the optical fiber joint 100.

  As shown in FIG. 5 a, the second sliding slot 2015 is disposed around the socket 201, the second sliding slot 2015 is spiral, and the second sliding slot 2015 is from one end of the socket 201. The tail end of the end of the second sliding slot 2015 extending in the circumferential direction along the socket is fixed to the lock point 1304. In this embodiment, the second sliding slot 2015 has the same shape as the sliding slot 1704 (see FIG. 3a) of the joint dust cap 170.

  As shown in FIG. 5 b, the optical fiber adapter 200 includes an O-shaped seal ring 222, a lock nut 220, an O-shaped seal ring 240, a socket body 210, and a ceramic ferrule 212. The O-shaped seal ring 240, the lock nut 220, and the O-shaped seal ring 240 are sequentially attached to the socket body 210, and the ceramic ferrule 212 is inserted into the other end of the socket body 210. It is fixed using.

  The optical fiber adapter 200 includes an adapter dustproof cap 230, and one end of the adapter dustproof cap 230 has an adapter holding cavity for holding the optical fiber adapter 200. The holding cavity is configured to hold the socket 201 when the optical fiber adapter 200 is inserted into the dust cap 230.

  When the optical fiber joint 100 is inserted into the optical fiber adapter 200, the horn-shaped opening of the sleeve of the inner sleeve member 140 is inserted with the positioning key 2014 of the sliding slot as a target, and the inner sleeve member 140 is inserted into the sliding slot 2012. As a result, the insertion core 150 is inserted into the cavity 2011, the locking point 1304 of the optical fiber joint slides into the second sliding slot 2015 of the optical fiber adapter, and the locking point 1304 is the tail end of the second sliding slot 2015. The optical fiber socket 201 is rotated so as to slide to the portion, thereby realizing the lock.

  Based on the foregoing technical solution, the fiber optic connector provided by this embodiment of the present invention seamlessly connects to the C-shaped slot of the fiber optic adapter by using a sleeve having a C-shaped opening in the fiber optic joint. Is done. In this way, blind insertion of the optical fiber joint can be carried out, which makes operation easier, thereby realizing plug and play of the optical fiber connector. The fiber optic connector provided by the embodiments of the present invention further achieves the highest waterproof grade.

  The foregoing descriptions are merely exemplary specific embodiments of the present invention, and are not intended to limit the protection scope of the present invention. Any variation or replacement within the technical scope disclosed in the present invention that can be easily understood by those skilled in the art shall fall within the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

DESCRIPTION OF SYMBOLS 100 Optical fiber joint 110 Optical cable 130 Outer sleeve member 132,136,172 O-shaped seal ring 134 Elastic part 138 Connection part 140 Inner sleeve member 150 Insert core 160 Rope 170 Joint dustproof cap 180 Sleeve 200 Optical fiber adapter 210 Socket main body 222, 240 O shape Seal ring 230 Dust-proof cap 300 Optical fiber joint 1302 Inclined boss 1304 Protrusion 1306 Restriction stage 1504 Restriction column part 2011 Cavity 2012 Slot 2014 Key 2015 Slide slot

Claims (13)

An optical fiber joint,
An optical cable,
An inner sleeve member having a cavity therein, wherein an optical fiber extending outside the optical cable is held in the cavity, one end portion of the inner sleeve member is fixed to the insertion core, and the sleeve is the other end An inner sleeve member disposed in the section;
An outer sleeve member, wherein the outer sleeve member is sleeved outside the inner sleeve member, and the outer sleeve member is rotatable about an axis about the sleeve; and
With
The sleeve of the inner sleeve member projects at least partially out of the outer sleeve member and projects out of the outer sleeve member such that a tail end of the sleeve forms a C-shaped cross section. The tail end of the
The insertion core, connection component, and elastic component are sequentially sleeved on the optical cable, and the elastic component is clamped between an end of the connection component and an end of the outer sleeve member,
A limiting column is disposed on the insert core, left and right limiting stages are provided on the outer sleeve member, the limiting column is limited by the left limiting stage and cannot be further rotated, and the limiting The column is limited by the right limit stage and cannot be rotated further.   The fiber optic joint of claim 1, wherein the C-shaped tail end of the sleeve is configured to connect to a C-shaped slot of a fiber optic adapter adapted to the fiber optic joint.   The optical fiber joint according to claim 1 or 2, wherein the opening of the sleeve is configured to connect to a positioning key of an optical fiber adapter adapted to the optical fiber joint.   The sleeve is configured to connect to a slot of a fiber optic adapter that conforms to the fiber optic joint, and the C-shaped cross section at the tail end of the sleeve matches a C-shaped cross section of the slot of the fiber optic adapter. Item 4. The optical fiber joint according to any one of Items 1 to 3.   The optical fiber joint according to any one of claims 1 to 4, wherein the opening of the sleeve has a horn shape.   The optical fiber joint according to claim 5, wherein an opening angle of the horn-shaped opening of the sleeve is 10 degrees or more and 30 degrees or less.   The optical fiber joint according to claim 6, wherein the opening angle of the horn-shaped opening of the sleeve is 15 degrees or 22.5 degrees.   The optical fiber joint according to any one of claims 1 to 7, wherein the insertion core is provided with a sleeve on the optical cable, and the connection component is provided with a sleeve at an end of the insertion core. An optical fiber connector comprising an optical fiber joint and an optical fiber adapter,
The optical fiber joint is
An optical cable,
An inner sleeve member having a cavity therein, wherein an optical fiber extending outside the optical cable is held in the cavity, one end of the inner sleeve member is fixed to the insertion core, and the sleeve is at the other end An inner sleeve member disposed;
An outer sleeve member, wherein the outer sleeve member is sleeved outside of the inner sleeve member, and the outer sleeve member is rotatable about an axis about the sleeve;
With
The sleeve of the inner sleeve member protrudes at least partially out of the outer sleeve member and the sleeve protrudes out of the outer sleeve member such that a tail end of the sleeve forms a C-shaped cross section. The tail end has an opening, the sleeve having a C-shaped opening is connected to the C-shaped slot of the optical fiber adapter, and the insertion core, the connecting component, and the elastic component are sequentially placed on the optical cable. And the elastic component is clamped between an end of the connection component and an end of the outer sleeve member, and a socket is disposed at one end of the optical fiber adapter and is configured to receive an optical fiber And the slot is disposed in the socket, the cavity is located in the middle of the socket, and the slot is A positioning key is disposed in the socket such that it surrounds the cavity and the slot forms a C-shaped cross section;
A limiting column is disposed on the insert core, left and right limiting stages are provided on the outer sleeve member, the limiting column is limited by the left limiting stage and cannot be further rotated, and the limiting The column part is an optical fiber connector that is restricted by the right restriction stage and cannot be further rotated. The optical fiber connector according to claim 9 , wherein an inner wall of the outer sleeve member of the optical fiber joint has at least one protrusion. The fiber optic connector of claim 9 , wherein at least one sliding slot is disposed on an outer surface of the socket of the fiber optic adapter. The optical fiber connector according to claim 10 or 11 , wherein the optical fiber joint is inserted into the optical fiber adapter, and the protrusion is connected to the sliding slot. The optical fiber connector according to any one of claims 9 to 11 , wherein the insertion core is provided with a sleeve on the optical cable, and the connection component is provided with a sleeve at an end of the insertion core.

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