KR200453177Y1 - fiber optic plug - Google Patents

Abstract

Relatively small fiber plugs make it easy to pull the fiber plug and associated fiber cable through a small passage. The shroud of the optical fiber plug protects the optical fiber connector and forms one or more, preferably a pair of openings. These openings are sized to receive a portion of the adapter sleeve after coupling the optical fiber plug to the outlet. The fiber plug may further comprise a cap installed to rotate relative to the rest, which serves as a tow grip during the installation of the fiber optic cable. In addition, the optical fiber plug may include a crimp band that is mechanically coupled to both the cable and the body, whereby the crimp band can isolate the optical fiber connector from torque due to the force applied to the cable.

Description

Fiber Optic Plugs {FIBER OPTIC PLUG}

The present invention relates to an assembly for connecting or disconnecting optical fibers, and more particularly, to an optical fiber plug coupled to an outlet.

Optical fiber is used for various telecommunications and data transmission. As a result, optical fiber networks must also have more and more junction boxes for connecting or terminating one or more optical fibers. For example, optical fiber networks, such as cable television (CATV) networks, have several optical network units (ONUs) for converting optical signals propagating along optical fibers into electrical signals. In addition, the telephone and CATV network may be provided with a plurality of network interface devices (NIDs); Each NID is associated with a particular subscriber. Upon receiving the optical signal, the NID divides these signals and routes them to a specific location, such as a telephone or CATV output. Like the ONU, the NID can convert an input optical signal into an electrical signal. The optical fiber network may be provided with several different junction boxes, including junction boxes for optically connecting various optical fibers. These junction boxes protect any type of fiber, specifically the part that connects the fiber, from moisture or other environmental factors.

ONU, NID and other types of junction boxes have one or more outlets for connecting the optical fibers of the optical fiber cable to the optical fibers in the junction box, respectively. The optical fibers in the junction box are connected or separated as necessary. In general, an outlet includes a housing having an interior space and an adapter sleeve fixed to the interior space of the housing. The adapter sleeve is designed to insert a pair of ferrules, each ferrule is installed at the ends of the plurality of optical fibers. One of the ferrules is connected to an optical fiber end inside the junction box extending from a cable, ribbon or fiber optic device, to facilitate connection or disconnection of the optical fiber. As discussed below, the remaining ferrules are mounted to an optical fiber outside the junction box that is followed by a cable, ribbon or fiber optic device. Alignment of the ferrule is achieved by the adapter sleeve, and the optical fibers mounted on each end of the ferrule are precisely aligned by ferrule guide pins or other alignment means.

An optical fiber plug is installed at the end of the optical fiber cable to engage with the outlet of the conventional junction box. Generally, the plug has a cylindrical body and an optical fiber connector, and the plug ferrule is located inside the cylindrical body. To protect the plug ferrules, the cylindrical body surrounds some or all of the optical fiber connectors. The end of the cylindrical plug body is open to access the ferrule, but slightly protrudes from the ferrule to further protect the ferrule. When the plug and the outlet are connected, ferrules are installed in the various optical fibers of the optical fiber cable so that the optical fibers of the optical fiber cable match or connect with each optical fiber in the junction box.

While engaging the plug and outlet, insert the plug ferrule into one end of the adapter sleeve of the outlet. Thus, the outlet ferrule connected to the optical fiber end inside the junction box of the cable, ribbon or optical fiber device is matched with the plug ferrule by the adapter. Due to this configuration of the conventional optical fiber plug, one end of the adapter sleeve is inserted into the open end of the plug body when inserting the plug ferrule into the adapter sleeve. Also, in order to keep the plug ferrule inside the adapter sleeve, the optical fiber connector and the adapter sleeve of the optical fiber plug are designed to be mechanically connected by a pair of latches or the like. Plug ferrules and adapter sleeves are effectively coupled by these latches, but have the disadvantage that the floatability between the plug ferrule and the adapter sleeves is limited by the mechanical coupling of the optical fiber connector and adapter sleeve.

After joining the plug to the outlet, a force may be applied to the fiber optic cable to generate torque to the fiber optic connector including the plug ferrule. When such torque is applied, there is a problem that the attenuation of the optical signal propagated through the optical fiber equipped with the plug ferrule becomes large. More seriously, this torque can damage the fiber. In general, optical fiber cables with optical fiber plugs are so flexible that only minimal torque is applied to the plug ferrules. Recently, however, there has been a tendency to install optical fiber plugs in much stiffer cables, such as reinforced fiber cables designed for outdoor use. Because of this stiffness of the fiber optic cable, the force acting on the cable is much easier to transfer to the plug ferrule, resulting in a greater torque on the plug ferrule. Since torque attenuates the optical signal, it is desirable to design the plug so that when the plug ferrule is mounted, the plug ferrule and the optical fiber are at least partially isolated from the force exerted by the optical fiber cable.

Before connecting to the outlet, the fiber optic cable, including the end of the plugged fiber optic cable, must be pulled and installed in the desired path. In some cases, fiber optic cables should be installed through ducts or other small passages that are not much larger than the fiber cables themselves. Since the plug body must be large enough to enclose and accommodate one end of the adapter sleeve, the size of the body may limit the minimum size of the duct or other passageway through which the fiber optic cable is installed. In view of the large amount of fiber optic cable installed these days, it is important to reduce the space required for installing the fiber optic cable, that is, the size of the duct, which is increasingly disadvantageous to limit the minimum size of the duct. However, to date, reducing the size of the duct through which the optical fiber cable is pulled is limited, at least in part due to the size of the plug body mounted at the end of the optical fiber cable.

In order to pull the fiber optic cable, when the fiber optic plug is fitted at the cable end, a traction grip is usually mounted at the cable front end including the fiber optic plug. The traction grip is designed to provide a part for connecting a rope, cable, etc., which is firmly coupled to an end of an optical fiber cable load coupled to the reinforcing element of the cable, and the rope can be used to pull the optical fiber cable. Since the fiber optic cable must be pulled along a certain cable path that is twisted or twisted, the traction grip must by design not exert an improper torque on the cable as it rotates and pulls the cable. In general, a tow grip designed to rotate relative to a fiber optic cable has many elements that must be connected to the fiber optic cable. These elements of the traction grip are connected to each other so that the elements to which the rope or cable is connected rotate with respect to the element directly connected to the fiber optic cable. Thus, it is possible to use a towing grip that rotates with respect to the fiber optic cable, but it would be desirable to provide a towing grip that is suitable for rotating with a simpler structure fiber optic to facilitate the use of the towing grip and reduce its cost.

According to the present invention, an improved optical fiber plug is provided. The optical fiber plug according to an embodiment of the present invention is designed to easily pull the optical fiber cable and related plugs through relatively small passages. Caps mounted on the remainder of the fiber plug to provide a mechanism to pull the cable in a relative rotation to allow the cable to be pulled through the passage more easily, while allowing for relative rotation of the cable while reducing the number of parts compared to conventional towing grips. It is provided. In addition, the optical fiber plug isolates the optical fiber connector as well as the plug ferrule from the torque generated by the force applied to the optical fiber cable.

According to one embodiment, the optical fiber plug includes a connector housing and a plug ferrule, wherein the plug ferrule may be partly located inside the housing and mounted at one end of the optical fiber. The optical fiber plug also includes a plug body that extends longitudinally between the first and second ends, which are both ends, and defines a longitudinal axis. The plug body has a shroud near the first end. In one embodiment, the shroud forms one or more openings that extend longitudinally from the middle of the shroud to the first end of the plug body. In a preferred embodiment, the shroud forms a pair of openings on both sides, the openings extending longitudinally from the middle of the shroud to the first end of the plug body. In other embodiments, there may be no openings in the shroud.

If the shroud is cylindrical and has a pair of openings, the first end of the shroud includes a pair of arcuate shroud portions separated by the openings. Preferably, these openings made of shrouds are aligned with each other. The optical fiber connector is located inside the plug body in a fixed position with respect to the plug body such that openings made of shrouds do not rotate about the longitudinal axis such that they are aligned longitudinally with the plug ferrule. In this regard, the plug ferrule generally has a plurality of holes formed in the reference plane in the longitudinal direction. Thus, the reference plane is located at the center of the openings made of the shroud.

According to one embodiment, an optical fiber assembly is provided in which an optical fiber outlet is designed to be connected to an optical fiber plug. The optical fiber outlet includes a housing having an inner space of which both first and second ends are open. The optical fiber outlet also includes an adapter sleeve that is installed in the interior space of the housing. The adapter sleeve forms a longitudinal passage for inserting a portion of the ferrule of the optical fiber plug. In this regard, the shroud protrudes somewhat from the plug ferrule while placing the plug ferrule inside the body to allow access to the plug ferrule inside the shroud through the first end of the plug body. In addition, after the plug ferrule of the optical fiber plug is inserted into the adapter sleeve, the shroud and the adapter sleeve are sized so that a part of the adapter sleeve is disposed inside the opening made of the shroud. Therefore, in this embodiment, the shroud does not completely surround the adapter sleeve as in the conventional optical fiber plug. Therefore, the size of the shroud is reduced compared to the conventional, so that the overall size of the optical fiber plug is reduced. The optical fiber plug is advantageous in that the optical fiber plug of the present embodiment can be pulled through a smaller duct or passage as compared to the prior art because the size of the duct or other passage that sometimes pulls the plug and associated cable is limited.

According to another embodiment of the present invention, there is provided an optical fiber plug having a connector housing and a plug ferrule, wherein at least a portion of the plug ferrule is located inside the housing. The optical fiber plug also has a crimp band. The first portion of the crimp band is suitable for being connected to the optical fiber connector and the second portion to the optical fiber cable. The optical fiber plug of this embodiment also includes a plug body forming a longitudinal axis. According to this embodiment, the crimp band and the plug body are each coupled to each other and have a coupling member for mechanically coupling the crimp band and the body while preventing relative rotation about the longitudinal axis. For example, a crimp band is provided with a key, and a plug body is provided with a passage in the longitudinal direction, and a key groove passes through the passage. Thus, a portion of the crimp band may be disposed in the passage made of the plug body so that the key engages with the key groove. In this embodiment, the key formed in the crimp band and the key groove formed in the plug body preferably extend in the longitudinal direction. Thus, while longitudinal movement between the crimp band and the plug body is allowed, relative rotation between them is prevented. By preventing relative rotation between the crimp band and the plug body, all torque received by the fiber optic cable is transmitted through the crimp band to the plug body and then to the housing of the outlet to which the fiber plug is connected. Therefore, the optical fiber connector and the plug ferrule are isolated from the torque received by the cable because the plug body, through which the optical fiber connector is connected through the coupling members of the crimp band and the plug body, is hardly moved by the torque of the optical fiber cable.

In one embodiment, the crimp band extends longitudinally between both first and second ends, and the first and second portions of the crimp band are close to the first and second ends, respectively. The key of the crimp band may be formed in the center between the first and second portions. On the other hand, there is a large diameter portion near the second portion of the crimp band, and a key may be formed in this portion. However, in any configuration, pressing the first and second portions of the crimp band can secure the crimp band to the optical fiber connector and the optical fiber cable. Even when the first and second ends are pressed, the portion where the key is located is only slightly deformed.

In one embodiment, the spring push is connected to the housing of the optical fiber connector. In this case, the first end of the crimp band is connected to the spring push. Specifically, the spring push may have a crimp body designed to be connected by the first portion of the crimp band. For the connection of the fiber optic cable by crimp band, there may be a support tube in the cable which is arranged inside the jacket of the fiber optic cable and surrounds a plurality of optical fibers. The support tube is aligned with the second portion of the crimp band to hold the cable jacket between the second portion and the support tube. Thus, the crimp band secures both the fiber optic cable and the connector. In addition, while the crimp band and the main body are mechanically coupled by the coupling members of the crimp band and the plug body, the relative rotation between them is prevented, thereby protecting the optical fiber connector and the plug ferrule from the influence of torque acting on the optical fiber cable. .

According to another embodiment, the main body of the optical fiber plug forms a longitudinal axis while extending longitudinally between both first and second ends. The optical fiber plug also includes an optical fiber connector having a connector housing and a plug ferrule, wherein a portion of the plug ferrule is located inside the housing. The optical fiber connector is located inside the plug body to allow access to the plug ferrule through the first end of the plug body. The optical fiber plug also includes a cap mounted to the plug body to cover the first end of the plug body. The cap is mounted to the plug body such that movement in the longitudinal direction is limited and rotates about the plug body about the longitudinal axis. Thus, the cap is connected to the rest of the body while rotating relative to the rest of the plug body. Thus, the cap effectively serves as a traction grip, and can pull the fiber optic cable connected to the fiber plug through the fiber plug and the passageway. In this regard, an opening through which a rope or a cable is connected may be formed in the cap so that the optical fiber plug and the cable can be easily pulled through the passage. The cap protects the fiber optic connector while pulling the plug and cable through the passage, as well as being relatively small compared to the plug body, and in fact need not be as large as the body. Therefore, the size of the passage for pulling the optical fiber plug and the cable is not substantially limited because of the cap.

The plug body includes a shaft and a collar mounted to the shaft, the collar being allowed to rotate about the longitudinal axis of the shaft with limited movement in the longitudinal direction. In one embodiment, the shaft has a thread and the collar has a female thread. Thus, the collar can be screwed onto the shaft for mounting. There is a shroud near the first end adjacent the axis of the plug body. The shroud is larger than the shaft so as to limit the movement of the collar by the screw of the shaft of one end and the shroud of the other end. The cap is connected to the collar to move with the collar. After the cap is removed, it is suitable to pull the fiber optic cable through the aisle and connect the collar to the fiber optic outlet in preparation for the connection of the fiber optic plug and the corresponding outlet.

By the present invention, the problems described above can be solved.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.
1 is an assembled perspective view of an optical fiber plug according to an embodiment of the present invention;
FIG. 2 is an exploded perspective view of FIG. 1, showing an optical fiber connector, a crimp band, a crimp band support, a buffer tube, an antenna, an optical fiber cable; FIG.
3 is a cross-sectional view taken along line 3-3 of FIG. 1;
4 is a perspective view of the optical fiber plug of FIG. 1 before inserting the plug body into the optical fiber connector along the optical fiber cable;
5 is a cross-sectional view taken along line 5-5 of FIG. 1;
6 is an exploded view of the optical fiber plug of FIG. 2 including an optical fiber cable, an inner support tube, a crimp band support, a reinforcing member, and an exposed optical fiber;
7 is a perspective view of a crimp band according to another embodiment of the present invention;
8 is a perspective view showing a coupling state of the optical fiber plug and the outlet of the present invention;
9 is an exploded perspective view of an optical fiber outlet for coupling an optical fiber plug of the present invention;
10 is a perspective view of the optical fiber plug of the present invention with the cap not yet mounted on the optical fiber plug;
11 is a perspective view of the optical fiber plug of FIG. 10 with a cap mounted on the remainder of the optical fiber plug;
12 is a perspective view of a plurality of outlets to which a plurality of optical fiber plugs are coupled;

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention. However, the present invention may be embodied in many other forms and should not be construed as limited to the embodiments set forth herein. In the drawings, the same reference numerals are given to the same parts.

1 shows an optical fiber plug 10 according to an embodiment of the present invention. The optical fiber plug is connected to the end of the optical fiber cable 12 and coupled to the corresponding optical fiber outlet. In general, the outlet is configured to be connected to the junction box such that an optical fiber (not shown) extending from the optical fiber cable is aligned and optically connected to the optical fiber inside the junction box. The optical fiber plug can be designed to couple with a variety of optical fiber outlets, but it is advantageous to design to couple to optical fiber outlets described in the US patent application entitled Fiber Optic Outlet.

As shown in Figs. 2-4, the optical fiber plug 10 includes a plug body 14 and an optical fiber connector 16, which are installed at the end of the optical fiber cable 12 and located inside the plug body. The optical fiber connector includes a housing 18 and a plug ferrule 20, a portion of which is located inside the housing. In this regard, the connector housing usually extends longitudinally between the rear end and the front ends 22, 24 and forms an internal passageway between both ends. Thus, the plug ferrule is installed inside the connector housing, and the front face 26 of the ferrule protrudes at the front end of the housing. In order to prevent the plug ferrule from overhanging at the front end of the connector housing, it is common for the connector housing to have correspondingly formed inner shoulders which abut against the shoulders 30 of the ferrule. However, it is also possible to restrict the connector housing from engaging the plug ferrule and projecting beyond the front end of the housing in other ways.

In addition to the connector housing 18 and the plug ferrule 20, the optical fiber connector 16 typically includes other elements depending on the type. Although the optical fiber plug may have various connectors, including an MTRJ connector, an SC-DC connector, a Unicam ^™ connector, an SC connector, an LC connector, and the like, the optical fiber plug 10 of the illustrated embodiment uses an MTP connector as an example, but is not limited thereto. It is not. Therefore, the MTP connector will be described in detail below. The MTP connector includes a connector housing that is rectangular in cross section and a multi-fiber plug ferrule that is also rectangular in cross section. As shown, the housing of the MTP connector has a large diameter near the rear end 22 and a small diameter near the front end 24. Thus, the MTP connector housing forms a jaw (not shown) between the large diameter portion and the small diameter portion. As shown in FIG. 2, the MTP plug ferrule also has a large diameter portion 32 near the rear end 34 and an axial portion 36 extending from this portion to the front face 26. Thus, the MTP plug ferrule also forms the jaw 30 between the large diameter portion and the shaft portion. Therefore, the inner jaw of the connector housing and the jaw of the MTP plug ferrule abut, preventing the plug ferrule from protruding from the front end of the connector housing. The MTP plug ferrule also has a window 28.

MTP connector 16 also includes a spring push 38 extending longitudinally between both ends 40, 42. Like the connector housing 18, the spring push forms an internal passage between both ends, through which the optical fiber passes. The front end of the spring push is inserted into the connector housing and engaged. For example, there is a pair of tabs 44 at the front end of the spring push, which tabs open side by side to engage corresponding grooves formed in the connector housing and open into the inner passage. The MTP connector housing includes a spring 46 disposed between the front end of the spring push and the rear end 34 of the plug ferrule 20, which causes the plug ferrule to be pushed forward inside the connector housing, thereby providing a front of the plug ferrule. 26 protrudes slightly out of the front end of the housing.

According to FIGS. 3-5, the plug body 14 of the optical fiber plug 10 extends between the first end 48 and the second end 50. The optical fiber connector 16 is located inside the body as shown in FIGS. 1 and 3, but may access the front face 26 of the plug ferrule 20 through the first end of the body. Thus, the plug body serves to protect the optical fiber connector while allowing access to the optical fiber mounted on the ferrule through the front of the plug ferrule. As will be appreciated by those skilled in the art, the plug body is configured to be coupled to the optical fiber outlet such that the optical fiber of the outlet ferrule and the optical fiber of the plug ferrule can be aligned and connected to each other.

The plug body 14 generally has shafts 52, 54. This axis extends in the longitudinal direction to form a passage in which the optical fiber connector 16 is disposed. In one embodiment, the shaft includes a truncated cone portion 52 near the second end 50 of the body and a cylindrical portion 54 forming the body middle portion. As shown, the truncated cone becomes larger in diameter as it goes from the second end of the body to the cylinder. The plug body also has a shroud 56 near the first end 48. As can be seen in Figures 1 and 4, the shroud extends from the cylindrical portion of the shaft to the first end. The shroud is also cylindrical, but slightly larger in diameter than the cylindrical portion of the shaft. Although the embodiment of the shaft having two ends as described above has been described, the shaft of the plug body may have a different shape. For example, it may have a shape having a constant taper from the second end to the first end of the plug body.

Once assembled, the optical fiber connector 16 is located inside the plug body 14, so that the main body protects the optical fiber connector. However, the front end of the front end 24 and the plug ferrule 20 of the housing 18 may be exposed to access the interior of the shroud 56 through the first end 48 of the body. Nevertheless, the first end of the main body preferably projects slightly from the front of the plug ferrule, so that damage to the front of the ferrule can be prevented during operation and installation.

One or a pair of openings 58 are provided at both sides of the shroud 56 so that the front end 26 of the connector housing 18 and the front face 26 of the plug ferrule 20 can be further accessed for cleaning or the like. It is good to form. These openings extend longitudinally from the middle of the shroud to the first end 48 of the body 14. Since the shroud is usually cylindrical, a pair of arches 60 are separated by the opening. The pair of openings formed by the shrouds are usually aligned with respect to the plug ferrule 20 as well as to each other, thereby facilitating the assembly of the optical fiber plug 10. In a general embodiment in which the plug ferrule forms a plurality of holes extending longitudinally from the reference plane, the opening formed by the shroud is preferably disposed about the reference plane. These openings may have a variety of sizes, but the width thereof is larger than the height of the connector housing 18, and preferably larger than the height of the adapter sleeve of the outlet into which the optical fiber plug is inserted. However, it is common that the cabinet formed by the opening is 90 degrees or less.

Therefore, the front end 26 of the connector housing 18 and the front face 26 of the plug ferrule 20 can be cleaned through the opening 58. In addition, during shipment and storage, a dust cap 61 is generally provided at the front end of the connector housing. Therefore, it is possible to easily access the dust cap through the opening to remove the dust cap. On the other hand, the arcuate shroud portion 60 protects the optical fiber connector 16 to protect the connector during handling, installation and while preparing to connect to the outlet. In this connection, the plug body 14 including the arcuate shroud portion and the opening is designed such that the front portion of the plug ferrule never comes in contact with an unnecessary portion of the optical fiber outlet while connecting the plug 10 and the outlet. In addition, although the opening is seen in the illustrated embodiment, such opening may not be present in some cases.

The plug body 14 is fitted to the optical fiber cable 12 for installation. Subsequently, the optical fiber connector 16 is installed at the end of the optical fiber cable (see Figs. 2-4). Fiber optic connectors can be installed at the cable ends in a number of ways. However, most preferred is to install a crimp band 62 on the optical fiber plug 10 for connecting the optical fiber connector to the cable. In this case, prepare an optical fiber cable first. 2, 3 and 6, the protective jacket 64 near the end of the optical fiber cable is removed to expose the reinforcing members 66 and the plurality of optical fibers 130. Next, the reinforcing members protrude from the protective jacket while cutting the reinforcing members so that the optical fiber protrudes from the reinforcing members. Although the optical fiber plug may be mounted to various types of optical fiber cables, the optical fiber cable having the central buffer tube 70 and the crimp band support tube 76 will be described, but the present invention is not limited thereto. In this case, there is an optical fiber in the buffer tube, and the buffer tube is cut while preparing the optical fiber cable between the protective jacket and the end of the reinforcing member.

Once the fiber optic cable is properly positioned, insert the crimp band 62, the spring push 38 and the spring 46 into the optical fiber cable 12, and then install the plug ferrule 20 at the end of the optical fiber 130, The optical fiber pops out into each hole of the plug ferrule. Next, the optical fiber is fixed to these holes with an adhesive or the like. After wiping the front face 26 of the plug ferrule and the end face of the optical fiber, the plug ferrule is inserted into the connector housing 18. Next, the spring push and the spring is pushed toward the rear end 22 of the connector housing, and the tab 44 of the spring push is coupled to the corresponding groove formed in the connector housing to connect the spring push and the connector housing. Thus, a spring is disposed between the spring push and the rear end 34 of the plug ferrule, pushing the plug ferrule forward so that the front of the ferrule is exposed through the front end 24 of the housing. Meanwhile, the end face of the optical fiber may be cleaned after inserting the plug ferrule into the connector housing.

Subsequently, the reinforcing member 66 protruding from the protective jacket 64 of the optical fiber cable 12 is inserted into the rear end 42 of the spring push 38. Then, the crimp band 62 is fitted to the spring push rear end such that the reinforcing member is positioned between the crimp band 62 and the spring push rear end. In this regard, the crimp band is generally a tubular member extending longitudinally between the first and second ends 72, 74. Thus, the first end of the crimp band surrounds the rear end of the spring push and the crimp band is disposed with the reinforcing member positioned therebetween. Next, the first end of the crimp band is squeezed so that the reinforcing member is firmly fixed between the first end of the crimp band and the rear end of the spring push. Thus, the crimp band is preferably composed of a material such as annealed brass that can maintain the crimp shape after being crimped. In order to provide adequate support when crimping the crimp band, the spring push is preferably made of a relatively hard material, such as hard plastic. Thus, the rear end of the spring push effectively serves as a crimp body. Although the crimp band has been described as a cylindrical shape and a spring push as a rectangular parallelepiped, the shape depends on the type of connector used, and thus, various shapes such as a cylindrical shape, an oval shape, a rectangular shape, a square shape, and a triangular shape can be taken.

According to the present invention, the crimp band is the optical fiber cable 12 at a point such that the reinforcing member 66 is fixed between the first end 72 of the crimp band 62 and the rear end 42 of the spring push 38. Can be fixed. Meanwhile, the crimp band may fix the optical fiber cable at two points apart from each other in the longitudinal direction. In addition to the above coupling method, the second end 74 may be configured to fix the protective jacket while surrounding the protective jacket 64 of the optical fiber cable. On the other hand, crimp bands can also be used to fix the fiber optic cable.

The optical fiber plug 10 may have a crimp band support tube 76 surrounding the inner support tube 68 to securely secure the second end 74 of the crimp band 62 to the protective jacket 64. . The crimp band support tube is generally made of a rigid material such as steel, and is fitted to the optical fiber 130 before installing the plug ferrule 20 at the end of the optical fiber. In particular, the support tube is inserted into the end of the optical fiber cable 12, but is disposed between the optical fiber and the reinforcing member 66, preferably between the buffer tube 70 and the reinforcing member. The support tube is disposed between the reinforcing member and the buffer tube of the optical fiber cable at a position aligned with the second portion of the crimp band. Therefore, the support tube serves to firmly support the protective jacket of the reinforcing member and the optical fiber cable when pressing the second portion of the crimp band. Also, in order to limit the advancement of the buffer tube during temperature cycling of the optical fiber cable, there is a stop jaw in the support tube.

In order to protect the optical fiber from water or other environmental factors, the optical fiber plug 10 may have a rim 78 usually made of silicon. Before installing the plug ferrule 20 at the end of the optical fiber, the fiber cable 12 and the crimp band 62 are fitted with a rim. Once the crimp band has been properly connected to the fiber optic cable and spring push 38, the rim can be pushed forward along the fiber optic cable until it abuts against the second end 74 of the crimp band. Since the tape is firmly fitted to the protective jacket 64 of the optical fiber cable, the optical fiber connector including the optical fiber is sealed around by the tape, thereby preventing environmental degradation.

In order to finish the assembly of the optical fiber plug 10, when the plug body 14 is advanced forward along the optical fiber cable 12 from the position in FIG. 4, the optical fiber connector 16 is located inside the inner passage consisting of the plug body. Advance to (see FIGS. 1 and 3). In order to easily install the optical fiber connector in the plug body, it is preferable to form the inner jaw 80 in contact with the second end or the rim 78 of the crimp band 62 on the plug body. Preferably, the optical fiber connector is sized so that the entire optical fiber connector is located inside the plug body while exposing the front face 26 of the plug ferrule 20 through the first end 48 of the plug body and the inner jaw is formed in the plug body. do. However, it is preferable that the first end of the plug body protrudes slightly from the front of the plug ferrule.

Once the optical fiber plug 10 is assembled, it is preferable to design the optical fiber plug of the present invention so that the plug body 14 does not rotate about the longitudinal axis with respect to the optical fiber connector 16. To this end, a coupling member may be formed in each of the plug body and the crimp band 62 to couple the crimp band and the plug body to each other to mechanically connect them, and to prevent relative rotation about the longitudinal axis. In the embodiment shown, the crimp band has a key 82 extending in the longitudinal direction (see FIGS. 2 and 4). Similarly, as shown in Fig. 5, the plug body has a passageway 84 and a keyway extending in the longitudinal direction, the keyway being sized to insert the key of the crimp band and open about the passage. During assembly, the key of the crimp band is inserted into the keyway to advance the plug body over the optical fiber connector in the direction of insertion into the passage of the plug body. Once the key is coupled to the passage, the plug body and the optical fiber connector can be moved longitudinally relative to each other while relative rotation about the longitudinal axis is prevented.

As shown in FIGS. 2-4, the key 82 is attached to the large diameter portion 86 near the second end 74 of the crimp band 62. However, this key may be in another part of the crimp band if necessary. For example, there may be a key in the middle of the clamp band (see FIG. 7). The plug body may have a key and the crimp band may have a passage. In addition, a key and a passage having different shapes and different coupling methods may be formed on the crimp band and the plug body, thereby preventing rotation.

As a result of mechanically connecting the plug body 14 to the crimp band 62 and the crimp band to the optical fiber cable 12, the optical fiber plug 10 effectively protects the optical fiber 130 from the effects of torque applied to the cable. do. In this regard, the force due to the torque applied to the fiber optic cable is transmitted along the fiber optic cable to the crimpband through the connection between the second portion 65 of the crimpband and the fiber optic cable. The force resulting from the torque is then transmitted from the crimp band to the plug body through the respective coupling member, eg the key 82 of the crimp band and the corresponding passage 84 formed in the plug body. The plug body transmits this force to the outlet to which the fiber plug is coupled. Since the outlet is firmly installed in the junction box, the optical fiber is effectively protected from the influence of the force due to the torque applied to the cable. For example, signals transmitted through an optical fiber should not be attenuated because of the torque received by the optical fiber cable. Although the optical fiber plug of the present invention can be installed in various optical fiber cables, it may be advantageous to install in a stiffer optical fiber cable which is designed for outdoor use and transmits a larger portion of the force due to torque to the optical fiber connector 16.

Once the optical fiber plug 10 has been assembled, the optical fiber plug can be coupled to the corresponding outlet 85 as shown in FIGS. In this regard, the first end of the plug body 14 is fitted to the outlet, but the front face 26 of the plug ferrule 20 is fitted to the adapter sleeve 87 of the cone center. As described in the patent application filed simultaneously under the name fiber optic receptacle, the shroud 56 has an alignment member that engages a pin, which is a corresponding alignment member of the receptacle, such as a groove 88 extending in the longitudinal direction, thereby providing a plug ferrule and an adapter sleeve. Should be aligned. Likewise, and as shown in Figs. 8 and 9, the housing 89 of the receptacle forms an internal cavity with both ends open and an adapter sleeve disposed therein. The adapter sleeve aligns with the outlet ferrule mounted at the end of the optical fiber which is connected through connecting the ferrule of the optical fiber plug, thereby aligning the optical fibers of the optical fiber plug with the corresponding optical fiber outlet. In addition, the optical fiber outlet may be provided with an adapter retainer 91 screwed into the optical fiber outlet housing to hold the biasing member and the adapter sleeve, such as a pair of springs 93, the biasing member being the outlet for the adapter sleeve. To the first end of the The outlet also has an inner seal, such as an O-ring 95, to protect the interior space of the outlet housing from moisture or other sources of environmental degradation. While the outlets shown in Figs. 8, 9 and 12 are advantageous, it should be understood that the optical fiber plugs can also be coupled to various other outlets if desired.

In order to securely connect the optical fiber plug 10 to the optical fiber outlet 85, the plug body 14 may further include a collar 90 designed to be placed on the shaft and screwed into the optical fiber outlet. In this connection, the collar is placed on the axis, so that the movement in the longitudinal direction is limited, but the relative rotation with the axis about the longitudinal axis is free. In one embodiment, the shaft includes male threads 92 some distance from the shroud. The collar must also have a corresponding female thread to be able to advance on the shaft while screwing in with the male screw on the shaft. According to this embodiment, once the collar is helically advanced and beyond the male threaded portion of the shaft, the collar can slide freely in the longitudinal direction with respect to the shaft. However, the forward movement of the collar about the axis is limited by the shroud 56. In this regard, the shroud is slightly larger than the shaft so that a jaw is formed between the shroud and the shaft. Also, because the shroud is larger than the collar, the forward movement of the collar relative to the shaft is limited in contact with the jaw formed between the shroud and the shaft.

According to FIG. 12, a plurality of optical fiber outlets 85 fixed to the junction box 120 such that the optical fibers protruding from the front face 26 of the plug ferrule 20 are optically connected in alignment with the optical fibers (not shown) in the junction box. It can be seen that a plurality of optical fiber plug 10 is coupled to the).

As shown in FIG. 10, the collar 90 generally has a male thread portion 96 that engages with the female thread portion 97 of the optical fiber outlet 85 to secure the optical fiber plug 10 to the outlet. The collar may include a knurled, slotted or ribbed portion 98 in which the collar can be held in hand and easily rotated about the axis.

Therefore, in order to couple the optical fiber plug 10 to the outlet 85 as shown in FIGS. 8 and 12, the plug is inserted into the outlet such that the front face 26 of the ferrule 20 of the optical fiber plug is inserted into the adapter sleeve of the outlet. To insert the ferrule of the optical fiber plug into the adapter sleeve, the shroud 56 is inserted into the outlet. To protect the interior of the optical fiber outlet from moisture or other environmental factors, a seal 95 may be formed in the shroud, such as an O-ring that is inserted into the circumferential groove to form a seal together of the outlet. The male portion 96 of the collar 90 engages the female portion 97 of the optical fiber outlet to turn the collar 90 about the axis of the plug body 14 to engage the optical fiber plug and the outlet. Therefore, all the forces due to the torque applied to the optical fiber cable and transmitted along the optical fiber cable to the crimp band 62 and the plug body are transmitted to the optical fiber outlet, to isolate the optical fiber 130 from all such deterioration causes.

According to one embodiment, the shroud is sized such that a portion of the adapter sleeve 87 into which the plug ferrule 20 is inserted is in the opening 58 made of the shroud 56. In this regard, after coupling the optical fiber plug 10 to the outlet 85, it is preferable that the lateral portion of the adapter sleeve is inside the opening by the shroud. In general, the shrouds of the present invention may be smaller in size than conventional designs, as the design requires that the shrouds completely surround the plug ferrules and eventually the adapter sleeve. Since the size of the plug body 14 including the shroud is a factor in limiting the size of the passage through which the optical fiber cable 12 is to be installed, the size of the shroud is made smaller than in the prior art, thereby reducing the plug body of the present invention. You can pull through the smaller passage.

To help install the optical fiber cable 12 with the optical fiber plug 10 mounted in the passage, a cap 100 covering at least the first end of the plug body 14 may be mounted to the plug body during installation (FIG. 10, 11). The cap is usually cylindrical, and one end of the cylindrical body is closed as a sphere or a circle. The interior of the cap is empty and fits into the collar 90 by fitting to the first end of the plug body. In this regard, inside the cap there is a female thread that engages the male thread portion 96 of the collar. When the cap is connected to the collar, the cap is freely rotated about the longitudinal axis with respect to the plug body, although movement in the longitudinal direction is limited. The cap is typically formed of stainless steel or other rigid material to protect the front end 24 of the connector housing 18 and the front face 26 of the plug ferrule 20, which is the same as the front end 24 of the connector housing 18. The front face 26 of the plug ferrule 20 may also be covered with a dust cap 61, as shown in FIG. Otherwise, the fiber optic cable is exposed through the first end of the plug body. As the cap rotates with respect to the optical fiber plug, a rope or cable can be connected to the cap, specifically the opening 102 formed in the cap, so that the cable with the optical fiber plug can be pulled through the passage. Even if the cable installation passage is bent or bent, the optical fiber cable and the plug with the optical fiber plug can be pulled through the cable installation passage while the cap rotates with respect to the optical fiber plug and the optical fiber cable. Thus, the optical fiber plug and cable are isolated from the force due to rotation and rotation. As a result, the optical fiber 130 is also isolated from the force of rotating the cap during installation. However, since the cap is directly connected to the collar of the plug body, the optical fiber cable can be rotated while having fewer parts than the conventional traction.

Pulling the optical fiber cable 12 through the passage and when ready to connect the optical fiber plug 10 to the outlet 85, the cap 100 is peeled off and the optical fiber plug and outlet are coupled as described above. Thus, collar 90 may be screwed into both the cap and the outlet.

While the present invention has been described with reference to some examples, the above description is merely an example, and the present invention is not limited to these examples, and is limited only by the appended claims.

Claims (3)

A connector housing and a plug ferrule, the plug ferrule comprising: a fiber optic connector at least partially located within the connector housing and capable of being mounted to one end of one or more optical fibers; And
Extending longitudinally between the first and second ends, both ends, having a cylindrical shroud near the first end, the shroud forming a pair of openings on both sides, the openings being at least from the middle of the shroud; A plug body extending longitudinally to one end;
And placing the optical fiber connector inside the plug body to access the plug ferrule inside the shroud through the first end of the plug body.
The optical fiber plug of claim 1 wherein the shroud comprises a pair of arcuate shroud portions separated by openings.
The optical fiber plug of claim 1 wherein the shroud comprises a pair of arcuate shrouds having different shapes.

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