RU2616069C2 - Fibre-optic connector - Google Patents

Abstract

FIELD: manufacturing technology.

SUBSTANCE: invention relates to fibre-optic connectors installed on operation site. Fibre-optic connector has fibre-optic cable connection unit and connected to it fibre-optic cable fixation unit. Fixation unit includes hollow housing and cover, corresponding to said housing so, that when cover closes hollow housing inner space for fibre-optic cable accommodation and fixation is developed. At that, hollow housing and cover are made on fibre-optic cable fixing unit one end. Said unit has threaded connecting part, together with hollow housing forming external thread and having through hole communicated with inner space, through which fibre without sheathing is passing.

EFFECT: technical result consists in creation of fibre-optic connector, which can be used for different types of fibre-optic cables, for example, for fixation of various types and sizes fibre-optic cables.

18 cl, 5 dwg

Description

FIELD OF THE INVENTION

The invention relates to a fiber optic connector, in particular mounted on-site.

State of the art

Fiber optic connectors are used in fiber optic communication systems. Due to the increasing use of optical fibers in local communication networks and with increasing requirements for fiber-optic access networks with bringing the optical cable to the user (FTTH, Fiber To The Home), the requirements for fiber-optic connectors are constantly growing. However, factory manufacturing using polishing and assembly is expensive and cannot meet these requirements, so the connector assembly work is preferably performed at the installation site, which increases the requirements for on-site fiber-optic connectors, the assembly of which should be quick and easy.

On-site fiber-optic connectors should minimize working hours, reduce labor costs, and they should ensure ease of operation. For example, it is acceptable if a reliable fiber optic connector can be assembled within a few minutes. An on-site fiber-optic connector mainly includes a fiber optic cable connection unit and a fiber-optic cable fixation unit firmly attached to it. In general, the method of assembling a fiber-optic connector mounted on the site of operation includes the following steps: releasing uninsulated fiber from the sheath for splicing by stripping a section of the protective layer of the fiber-optic cable; introducing sheathed fiber into the fiber optic cable connection unit through the fiber optic cable fixing unit to form a butt joint with the inserted optical fiber. In particular, during the installation process, the fiber is pushed forward so that it bends slightly inside the module fixing unit, resulting in a good butt joint of the fibers. Then, the fiber optic cable is temporarily fixed in the fixing unit and the butt-joined optical fibers are compressed by the connection unit to butt-joint the fibers. After this, the temporarily fixed fiber optic cable is released to return the fiber to a straight-shaped state, and the fixing sleeve is mounted on the fixing unit to fix the fiber optic cable in the fiber optic connector.

Various types of optical fibers can be used at the place of use, for example, round fiber optic cables of various diameters, fiber optic cables in the form of a figure eight, etc. However, a conventional fiber optic cable fixing assembly is usually adapted to only one particular type of fiber optic cable, therefore, traditional fiber optic connectors are used only for a particular type of fiber optic cable, for example, a round fiber cable with a diameter of 3 mm. Thus, traditional fiber optic connectors are not adapted for splicing various types of fiber optic cables.

Disclosure of invention

The objective of the invention is to provide a fiber optic connector that can be used for various types of fiber optic cables, in particular, the fixation unit of such a fiber optic connector must fix fiber optic cables of various types and sizes so that the fiber optic connector can be used for splicing fiber Optical cables of various types and sizes.

In accordance with the present invention, the fiber optic connector comprises a fiber optic cable connection unit and a fiber optic cable fixation unit connected to it, characterized in that the fiber optic cable fixation unit includes a hollow body and a cover, which when mounted on a hollow the housing closes it, forming a space for the location and fixation of the fiber optic cable in it.

The cover may be rotatable with the hollow body. In particular, the lid can be made integrally with the hollow body, while it has the ability to rotate relative to this hollow body. In addition, the lid and the hollow body can be made integrally of plastic, and the junction has a reduced thickness to allow rotation of the cover relative to the hollow body.

Alternatively, the cover can be made separately from the hollow body, so that the cover is a removable part and has the ability to be fixed on the hollow body using fixing elements.

Both the hollow body and the cover in cross section are substantially semicircular in shape, and the interior space has a substantially circular cross section.

In addition, both the hollow body and the lid may have protrusions directed toward the interior.

The protrusions on the hollow body can be located opposite the protrusions on the cover. In addition, the protrusions on the hollow body and the protrusions on the lid are made in the form of strips located essentially perpendicular to the longitudinal direction of the hollow body. The edge of the at least one strip-shaped protrusion directed towards the protective layer of the fixed optical fiber can have at least one small protrusion directed toward the interior space. This small protrusion may have a conical shape.

The hollow body and the cover can be made at one end of the fixation unit of the fiber optic cable, and this node has a threaded connecting part connected to the hollow body, forming an external thread together with the hollow body. In this case, the threaded connecting part has a through hole, which communicates with the inner space and through which the fiber passes without a sheath. Additionally, the fiber optic connector includes a locking sleeve with an internal thread corresponding to the specified external thread.

In addition, a longitudinal groove is made on the threaded connecting part, which in the radial direction reaches the through hole, so that the fiber without the sheath can be radially guided by this longitudinal groove.

On the threaded connecting part can be made of the receiving channel, passing along the entire threaded connecting part.

In addition, a groove is made on the threaded connecting part, extending along the entire threaded connecting part and located in a place different from the location of the receiving channel. This groove is configured to accommodate the outer protective layer of the figure eight fiber optic cable, so that the groove and the internal thread of the sleeve together form a second locking structure for containing and fixing the outer protective layer of the figure eight fiber cable. The hollow body or cover on the side closest to the threaded connecting portion and adjacent to the groove has an opening through which the outer protective layer of the figure-eight fiber optic cable is withdrawn from the interior into the groove.

Alternatively, both the hollow body and the lid on the side of the hollow body closest to the threaded connecting part and adjacent to the junction of the body with the cover have cutouts, the cutout on the hollow body and the cutout on the cover together form an opening through which the outer protective layer a fiber optic cable having the shape of a figure eight is output from the interior; at the same time, a groove is made on the threaded connecting part in a place corresponding to the position of the indicated hole, which extends along the entire threaded connecting part and is adapted to receive the outer protective layer of the fiber-optic cable having the shape of a figure eight, and to withdraw it from the inner space, so that the groove and the internal thread together form a second locking structure for fixing the outer protective layer of the fiber optic cable having the shape of a figure eight.

A longitudinal groove is made on the threaded connecting part, which is located in a place different from the location of the groove and the receiving channel, and this longitudinal groove in the radial direction reaches the through hole, so that the fiber without the sheath can be radially inserted into this groove.

The fixation unit of the fiber optic cable, on the other hand, has an end of installation and connection, so that a threaded connecting part is located between this end and the hollow body; however, this end is made with the possibility of introducing into the hole the connection node of the fiber optic cable and connection with it.

In particular, the fiber optic cable connection unit on two opposite sides is provided with a pair of connection holes, and the end of the installation and connection has a pair of connection tabs for snapping on the corresponding connection holes.

The fiber optic connector in accordance with the present invention can splicing on-site round fiber optic cables of various sizes, as well as figure eight fiber optic cables.

The invention will be better understood from the further detailed description of the options for its implementation with reference to the drawings.

Brief Description of the Drawings

1 shows a fiber optic connector in accordance with one embodiment of the invention, a perspective view;

figure 2 - node fixing the fiber optic cable in accordance with one embodiment of the invention, a perspective view;

figure 3 is the same side view;

figure 4 is the same, front view with the cover removed;

figure 5 is the same, rear view.

Embodiments of the invention

In the following, specific embodiments of the invention will be described in detail with reference to the drawings, with like elements being denoted by like reference numerals. However, the present invention can be implemented in many different ways and should not be limited to the described options, which disclose the invention with sufficient completeness and fully reflect its concept for specialists in this field of technology.

As shown in FIG. 1, the fiber optic connector in accordance with the present invention comprises a fiber optic cable connection unit 4 and a fiber optic cable fixation unit 5 connected thereto, wherein the fixation unit 5 includes a hollow body 2 and a cover 1 which, when installed on the hollow body 2, closes it, forming a space for the location and fixation of the fiber optic cable in it.

The cover 1 can be connected with the hollow body 2 with the possibility of rotation.

In particular, the cover 1 can rotate relative to the hollow body 2, and the cover 1 and the hollow body 2 can be molded as a single part, and in the place E, where the cover 1 is connected to the hollow body 2, a hinge is formed, so that one side of the cover 1 is connected to the possibility of rotation to one side of the housing 2. When the cover 1 closes the hollow housing 2, the other side of the cover 1 comes into contact with the other side of the housing 2, so that the housing 2 and the cover 1 form an internal space for compression and fixation of the optical fiber cable. For example, a fiber optic cable can be compressed and fixed when the cover 1 clicks on the hollow body 2.

In the described embodiment, the lid 1 and the hollow body 2 are molded as a single piece of plastic, and the connection E, where the lid 1 is connected to the hollow body 2, has a reduced thickness so that the lid 1 can rotate relative to the hollow body 2.

Although not shown in the figures, the cover 1 can be separated from the hollow body 2, and then they are again assembled together. In particular, both the lid 1 and the housing 2 can be made in the form of separate elements, while the lid 1 is attached as a removable part to the housing 2 by means of fixing elements.

As shown in FIGS. 1 and 2, both the lid 1 and the hollow body 2 have a substantially semicircular shape in cross section, and the interior space in a cross section has a substantially circular shape. In the described embodiment, the edge of the other side of the lid 1 can be located above the edge of the other side of the hollow body 2, and when the lid 1 is pushed down, two of these edges are in contact. In this case, the fiber optic cable placed in this space is clamped. In another embodiment, the edge of the other side of the cover 1 may extend beyond the edge of the other side of the hollow body 2, and the fiber optic cable may be pressed by the cover 1 to the edge of the other side of the hollow body 2. In this case, the other side of the cover 1 can be attached to the hollow body 2 as a removable part using fixing means.

As shown in FIGS. 1-3, both the lid 1 and the hollow body 2 have inwardly projecting protrusions 11 to further limit space in order to more securely fix the fiber optic cable. As shown in FIGS. 1 and 2, the positions of the protrusions 11 on the hollow body 2 are directed opposite to the protrusions 11 on the cover 1. Alternatively, the protrusions 11 on the hollow body 2 and the protrusions on the cover 1 can be staggered relative to each other.

In the described embodiment, the protrusions 11 on the hollow body 2 and the protrusions 11 on the cover 1 are made in the form of strips located perpendicular to the longitudinal direction of the hollow body 2. In addition, as shown in FIGS. 2 and 3, there is at least one inwardly directed protrusion in the form of a strip, on the edge of which, intended for contact with the protective layer of a fixed optical fiber, is located at least one small protrusion 12 directed towards the inner space. In addition, at least one small protrusion 12 may be provided on the edge of each strip protrusion to further limit the interior space. The small protrusion 12 may have a conical or other shape, for example in the form of a column, so that it can bite the protective layer of the optical fiber, which must be fixed, or for its tight compression.

The design described above with the protrusions 11 allows you to effectively fix the protective layer of the optical fiber.

As shown in FIG. 1, the hollow body 2 and the lid 1 are formed at one end of the fiber optic cable fixing unit 5; while this node has a threaded connecting part 52 (figure 4), which is connected to the hollow body 2 and forms with it an external thread. In this case, the threaded connecting portion 52 further has a through hole 54, which communicates with the above space and through which the fiber D passes without a sheath. The fiber optic connector also includes a locking sleeve 7, which has an internal thread corresponding to the above external thread. After fiber splicing is performed using the fiber optic assembly 4, the fixing sleeve 7 fixes the fiber optic cable in the assembly 5.

As shown in FIGS. 2 and 3, the threaded connecting portion 52 has a longitudinal groove 53, which radially reaches the through hole 54 (in this case, the through hole 54 has the shape of a groove), and the fiber D without the sheath when it is moved during installation this longitudinal groove 53 can be radially directed into the through hole. An installed fiber D without a sheath can be seen from the outside through a longitudinal groove 53.

As shown in FIG. 5, a receiving channel 521 is formed on the threaded connecting portion 52 by cutting off at least a portion of the height of the thread teeth along the entire threaded connecting portion 52. In the described embodiment, a portion of the thread teeth still remains in the region of the receiving channel 521 (i.e., the receiving channel 521 extends along a portion of the radial height of the thread teeth on the connecting portion 52, so that this channel 521 still functions as a thread). The receiving channel 521 and the internal thread together form the first fixing structure, adapted to accommodate and fix the reinforcing bundle of fibers A, for example from Kevlar surrounding the fiber optic cable. Alternatively, the receiving channel 521 may extend through the entire radial height of the thread teeth on the threaded connecting portion 52. After connecting the fixing sleeve 7 threaded to the threaded connecting part, the protective layer surrounding the optical fiber cable is fixed, fixing the optical fiber cable. Also in the receiving channel 521 can be fixed to the outer protective layer B or C (figure 1) of the fiber optic cable in the form of a figure eight.

As shown in FIG. 2, both the hollow body 2 and the cover 1 on the side closer to the threaded connecting portion 52 have a cutout 21. In this case, the cutouts 21 in the housing 2 and in the cover 1 together form one hole through which the outlet the outer protective layer B or C of the figure eight fiber optic cable. A groove 523 is made on the threaded connecting part 52 at a location corresponding to the location of the indicated hole for receiving the outer protective layer B or C of a fiber-optic cable having the shape of a figure eight, and this groove runs along the entire threaded connecting part 52. This groove together with internal thread forms a second locking structure for containing and fixing the outer protective layer of the fiber optic cable, having the shape of a figure eight.

The hole described above can only be made in a hollow housing or only in a cover. In particular, a groove 523 is made on the threaded connection portion 52, extending along the entire threaded connection portion 52 and located at a location different from the location of the receiving channel 521, the groove being configured to receive the outer protective layer C of the fiber optic cable having the shape figure eight, so that the groove and internal thread of the sleeve together form a second locking structure for receiving and fixing the outer protective layer of the fiber optic cable having the shape of a figure eight. The hollow body 2 or cover 1 on the side of the end of the body closest to the threaded joint 5 of the connection and adjacent to the groove 523 has an opening through which the outer protective layer C of the fiber-optic cable having the shape of a figure eight is removed from the inner space into the groove 523.

After attaching the fixing sleeve 7 threaded to the thread of the connecting part, the outer protective layer C of the figure eight fiber optic cable can be fixed, and this fiber optic cable can be fixed.

The groove 523, the receiving channel 521 and the longitudinal groove 53 can be made on the threaded connecting part 52. In particular, the longitudinal groove 53 is made on the threaded connecting part 52 in a place different from the location of the groove 523 and the receiving channel 521. The longitudinal groove 53 radially extends to the through hole 54 (in this case, the through hole 54 is in the form of a groove) so that the fiber D without the sheath can be inserted radially through the groove 53 into the through hole. The inserted fiber D without the sheath can be seen from the outside through the longitudinal Seventh groove 53.

The fiber optic cable fixing unit 5, on the other hand, has an installation and connection end 55, so that a threaded connecting part 52 is located between this end 55 and the hollow body 2. At the same time, said end (55) is adapted to be inserted into the opening of the assembly (4 ) connection of the fiber optic cable and connection with it, as shown in figure 1.

A snap connection may be formed between the fiber optic cable fixing unit 5 and the fiber optic cable connection unit 4. In particular, the fiber optic cable connection unit 4 is provided with a pair of connection holes 41 on two opposite sides, and the installation and connection end 55 has a pair of connection tabs 51 for snapping onto the corresponding connection holes.

Fiber optic connector operates as follows.

First, part of the protective layer of the fiber optic cable is removed to release the fiber for splicing. Then, the fiber without the sheath is lowered into the inside of the fixation unit 5 of the fiber optic cable and pushed forward so that the fiber is guided inside the fixation unit 5. Moreover, from the side of the groove 53 (or through the hole) it is very easy to observe the process of fiber introduction, which guarantees good splicing of the optical fibers. After splicing, the introduced fiber without a sheath is released and a fixing sleeve 7 is mounted on the thread fixing unit 5, finally fixing or fixing the optical fiber cable. After that, the outer and protective sheaths are installed in the fiber-optic connector and the connection or splicing of the optical fibers is completed.

When splicing a round fiber optic cable, this cable is placed in the space formed by the hollow body and cover; and reinforcing tapes A, for example from Kevlar, are placed in the receiving channel 521. When the internal thread of the fixing sleeve 7 is connected to the external thread, Kevlar is fixed and the round optical fiber is fixed.

When splicing a figure eight fiber optic cable, the outer protective layer is cut off on the top side of this fiber optic cable and the outer protective layer C on the underside of the fiber optic cable is passed through an opening into the groove 523 in the corresponding position of the external thread. When the internal thread of the fixing sleeve 7 is connected to the external thread, the outer protective layer C of the figure-eight fiber optic cable is fixed in the groove 523, thereby fixing or securing the fiber optic cable.

It should be noted that the outer sheath of the fiber-optic cable, having the shape of a figure of eight, can be fixed inside the space formed by the hollow body 2 and the cover 1, only with the help of these bodies 2 and the cover 1 without conducting the outer sheath of the cable from the inner space into the groove 523.

Although several illustrative embodiments of the invention have been shown and described, those skilled in the art will appreciate that various changes or modifications can be made in these embodiments without going beyond the principles and ideas of the disclosed invention, the scope of which is defined by the features contained in the claims , and their equivalents.

Claims (18)

1. A fiber optic connector comprising a node (4) for connecting a fiber optic cable and a node (5) for fixing the fiber optic cable connected to it, including a hollow body (2) and a cover (1), which when mounted on a hollow the casing closes it, forming a space for arranging and fixing the fiber optic cable in it, characterized in that the hollow casing (2) and the cover (1) are made at one end of the fiber optic cable fixing unit (5), said node having connected with hollow body (2) threaded dinitelnuyu portion (52) forming a hollow body with an external thread and having a through hole (54) which communicates with the internal space and through which the fiber is uncoated; however, the fiber optic connector further comprises a locking sleeve (7) with an internal thread corresponding to the specified external thread. 2. The fiber optic connector according to claim 1, characterized in that the cover (1) is rotatably connected to the hollow body (2). 3. The fiber optic connector according to claim 2, characterized in that the cover (1) is made integrally with the hollow body (2), while the cover (1) has the ability to rotate relative to the hollow body (2). 4. The fiber optic connector according to claim 3, characterized in that the cover (1) and the hollow body (2) are made in one piece from plastic, and the place of their connection has a reduced thickness to ensure rotation of the cover (1) relative to the hollow body ( 2). 5. The fiber optic connector according to claim 1, characterized in that the cover (1) is made separately from the hollow body (2), so that the cover (1) is a removable part and can be fixed to the hollow body using fixing elements. 6. The fiber optic connector according to claim 1, characterized in that both the hollow body (2) and the cover (1) in the cross section are essentially semicircular in shape and the interior space has a substantially circular cross section. 7. The fiber optic connector according to claim 1, characterized in that both the hollow body (2) and the cover (1) have protrusions (11) directed towards the inner space. 8. The fiber optic connector according to claim 7, characterized in that the protrusions (11) on the hollow body (2) are located opposite the protrusions (11) on the cover (1). 9. The fiber optic connector according to claim 8, characterized in that the protrusions (11) on the hollow body (2) and the protrusions (11) on the cover (1) are made in the form of strips located essentially perpendicular to the longitudinal direction of the hollow body. 10. The fiber-optic connector according to claim 9, characterized in that the edge of the at least one strip-shaped protrusion directed towards the protective layer of the fixed optical fiber has at least one small protrusion (12) directed towards the inner space. 11. The fiber optic connector according to claim 1, characterized in that a longitudinal groove (53) is made on the threaded connecting part (52), which in the radial direction reaches the through hole (54), so that the fiber (D) without a sheath can this longitudinal groove (53) to be directed in the radial direction. 12. The fiber optic connector according to claim 1, characterized in that a receiving channel (521) is made on the threaded connecting part (52), extending along the entire threaded connecting part (52). 13. The fiber optic connector according to claim 12, characterized in that a groove (523) is made on the threaded connecting part (52), extending along the entire threaded connecting part (52) and located in a place different from the location of the receiving channel (521 ), and the groove is designed to accommodate the outer protective layer (C) of the figure eight fiber optic cable, so that the groove and the internal thread of the sleeve together form a second locking structure for containing and fixing the outer protective layer of the optical fiber an eight-shaped cable; in this case, the hollow body or cover from the side closest to the threaded connecting part and adjacent to the groove (523) has an opening through which the outer protective layer (C) of the figure-eight fiber optic cable is removed from the inner space into the groove (523) ) 14. The fiber optic connector according to claim 12, characterized in that both the hollow body and the lid on the side of the hollow body closest to the threaded connecting part and adjacent to the housing (l) connecting point to the cover have cutouts (21), moreover, the cutout on the hollow body and the cutout on the lid together form an opening through which the outer protective layer (C) of the figure eight fiber optic cable is removed from the inner space; at the same time, a groove (523) is made on the threaded connecting part (52) in a place corresponding to the position of the indicated hole, which extends along the entire threaded connecting part (52) and is adapted to accommodate the outer protective layer (C) of a fiber optic cable having the form eight, and its withdrawal from the inner space, so that the groove and the internal thread together form a second locking structure for fixing the outer protective layer of the fiber optic cable having the shape of a figure eight. 15. The fiber optic connector according to claim 13, characterized in that a longitudinal groove (53) is made on the threaded connecting part (52), located at a location other than the location of the groove (523) and the receiving channel (521), this the longitudinal groove in the radial direction reaches the through hole (54), so that the fiber (D) without the sheath can be radially inserted into this groove (53). 16. The fiber optic connector according to claim 14, characterized in that a longitudinal groove (53) is made on the threaded connecting part (52), located at a location other than the location of the groove (523) and the receiving channel (521), this the longitudinal groove in the radial direction reaches the through hole (54), so that the fiber (D) without the sheath can be radially inserted into this groove (53). 17. The fiber optic connector according to claim 1, characterized in that the fiber optic cable fixing unit (5), on the other hand, has an installation and connection end (55), so that a threaded connecting part (52) is located between this end ( 55) and a hollow body (2); however, the specified end (55) is made with the possibility of introducing into the hole of the node (4) the connection of the fiber optic cable and connection with it. 18. The fiber optic connector according to claim 17, characterized in that the node (4) for connecting the fiber optic cable from two opposite sides is provided with a pair of connecting holes (41), and the end (55) of the installation and connection has a pair of connecting protrusions (51 ) to snap into the corresponding connecting holes.

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