CN203350483U - Optical fiber connector - Google Patents

Abstract

The utility model discloses an optical fiber connector which comprises: a core insert assembly; a crimping body which sleeves the core insert assembly; and a housing. The core insert assembly, along with the crimping body, is installed in the housing. The crimping body and the housing are constructed to mutually maintain at a first installation position and a second installation position. At the first installation position, the core insert assembly can be separated from the housing and can rotate relative to the housing. At the second installation position, the core insert assembly is jointed with the housing and cannot rotate relative to the housing. Accordingly, the grinding of an end face of the no-slope plane of the core insert assembly and adjusting an angle of the core insert assembly can be carried out at the first installation position, and the grinding of a bevel angle end face of the core insert assembly can be carried out at the second installation position. Moreover, cleaning end faces of the connector does not enable the core insert assembly to rotate. Accordingly, the connector provided by the utility model can be applicable to various production stages of connectors, and can ensure the reliability of a connector. In addition, the utility model also provides a manufacture and assembly method of the connector.

Description

The joints of optical fibre

Technical field

The utility model relates to joints of optical fibre field, relates in particular to a kind of joints of optical fibre and manufacture thereof and assembly method.

Background technology

Figure 13 has shown a kind of perspective exploded view of the existing SC type joints of optical fibre; Figure 14 shows that the ferrule assembly in Figure 13 is assembled into the schematic diagram in inner casing together in company with crimp body.

As shown in Figure 13 and Figure 14, the existing SC type joints of optical fibre mainly comprise crimp body 10, inner housing 20, ferrule assembly 30, spring 40 and shell body 50.

As shown in Figure 13 and Figure 14, during assembling, spring 40 is contained in crimp body 10 and between crimp body 10 and ferrule assembly 30, crimp body 10 is enclosed within on ferrule assembly 30, ferrule assembly 30 is installed in inner housing 20 together in company with crimp body 10, and then inner housing 20 is installed in shell body 50.

As shown in Figure 13 and Figure 14, ferrule assembly 30 mainly comprises lock pin 31 and is positioned at the back seat 32 of lock pin 31 rear ends, be evenly distributed with a plurality of protruding 33 on back seat 32, for the respective slot with in inner housing 20, coordinate, in addition, also be connected with an encapsulating pipe 34 at the rear portion of back seat 32, for the endoporus to lock pin 31, inject glue, in order to optical fiber is fixed in the endoporus of lock pin 31.

Refer to Figure 13 and Figure 14, in the existing SC type joints of optical fibre, be formed with a projection 11 on the periphery of crimp body 10, form the groove 21 of a correspondence on inner housing 20 simultaneously, as shown in figure 14, when the projection 11 on crimp body 10 is fastened togather with the groove 21 on inner housing 20, just ferrule assembly 30, spring 40 are assembled in inner housing 20 together with crimp body 10.

But, in the existing SC type joints of optical fibre, in order to guarantee the angle that can regulate ferrule assembly when polishing the end face of ferrule assembly 30, for example, when the ferrule assembly of the SC type joints of optical fibre that manufacture angle physical contact (APC), therefore, for the existing SC type joints of optical fibre, when ferrule assembly 30, when spring 40 is assembled in inner housing 20 together with crimp body 10, ferrule assembly 30 still can be with respect to inner housing 20 rotations, be projection 303 on the back seat 302 of ferrule assembly 30 still can be easily with inner housing 20 in respective slot break away from, so that the angle to ferrule assembly 30 is adjusted.

But, for this existing SC-APC joints of optical fibre, when the end face of the ferrule assembly of clear light fiber connector, easily cause the end face big angle rotary of ferrule assembly, cause that loss increases thereupon, and excessive when ferrule assembly rotation, can cause between the SC-APC joints of optical fibre the correctly problem of interworking.

Therefore, a kind of angle that can either be convenient to regulate ferrule assembly when manufacturing and assemble need to be provided, the joints of optical fibre of ferrule assembly rotation can be when clean, can not caused again.

The utility model content

The purpose of this utility model is intended to solve at least one aspect of the above-mentioned problems in the prior art and defect.

A purpose of the present utility model is to provide a kind of joints of optical fibre of novelty, and the angle that it can be convenient to regulate ferrule assembly when manufacturing and assemble can not cause the ferrule assembly rotation again when the end face of clean ferrule assembly.

According to an aspect of the present utility model, a kind of joints of optical fibre are provided, comprising: ferrule assembly; Crimp body, be enclosed within on described ferrule assembly; And housing, described ferrule assembly is installed in described housing together in company with described crimp body, wherein, described crimp body and described housing are configured to mutually remain on the first installation site and the second installation site, and when in the first installation site, described ferrule assembly can separate with described housing, and can be with respect to described housing rotation, when in the second installation site, described ferrule assembly engages with described housing, can not be with respect to described housing rotation.

According to an example embodiments of the present utility model, the described joints of optical fibre also comprise: spring, be contained in crimp body and between described crimp body and described ferrule assembly, when in the second installation site, described spring is compressed on described ferrule assembly, makes described ferrule assembly engage with described housing.

According to another example embodiments of the present utility model, when in the first installation site, described spring is not squeezed or slightly is squeezed.

According to another example embodiments of the present utility model, be formed with the first projection and the second projection on the periphery wall of described crimp body, described the first projection and described the second projection preset distance apart on described crimp body axial; Be formed with the first groove and the second groove on described housing, when in the first installation site, described the first projection is snapped in described the first groove, thereby makes described crimp body and described housing be maintained at the first installed position; When in the second installation site, described the first projection is snapped in described the second groove, and described the second projection is snapped in described the first groove, thereby makes described crimp body and described housing be maintained at the second installed position.

According to another example embodiments of the present utility model, described the first projection and described the second projection are the arc convex section of extending along the periphery of described crimp body.

According to another example embodiments of the present utility model, described the first projection and described the second projection described crimp body axially on before and after align; And described the first groove and described the second groove described housing axially on before and after alignment.

According to another example embodiments of the present utility model, the circumferential lengths of described the first projection is less than the circumferential lengths of described the second projection; And the width of described the first groove is greater than the width of described the second groove.

According to another example embodiments of the present utility model, described the first groove and described the second groove are interconnected, and make described the first projection to enter described the second groove from described the first groove unobstructedly.

According to another example embodiments of the present utility model, described the first groove and described the second groove are spaced from each other, and make described the first projection need to overcome predetermined interference drag and could enter described the second groove from described the first groove.

According to another example embodiments of the present utility model, be formed with the first projection and the second projection on the periphery wall of described crimp body, described the first projection and described the second projection described crimp body axially on preset distance apart, and upwards mutually stagger in week; Be formed with the first groove and the second groove on described housing, described the first groove and described the second groove mutually stagger on the periphery of described housing, and described the first projection can slide into the second position from the first position in described the first groove, when in the first installation site, described the first projection is snapped into the first position in described the first groove, thereby makes described crimp body and described housing be maintained at the first installed position; When in the second installation site, described the first projection slides into the second position in described the first groove, and described the second projection is snapped in described the second groove, thereby makes described crimp body and described housing be maintained at the second installed position.

According to another example embodiments of the present utility model, described the first projection and described the second projection are the arc convex section of extending along the periphery of described crimp body.

According to another example embodiments of the present utility model, the circumferential lengths of described the first projection is less than the circumferential lengths of described the second projection; And the width of described the first groove is greater than the width of described the second groove.

According to another example embodiments of the present utility model, described ferrule assembly comprises: lock pin, there is endoporus, and optical fiber is fixed in this endoporus; And back seat, be sleeved on the rear end of described lock pin.

According to another example embodiments of the present utility model, on the periphery of described back seat evenly and compartment of terrain be distributed with a plurality of projections; And be formed with the groove coordinated with described a plurality of projections in described housing, when spring pushing back seat, the projection of described back seat engages with the groove in described housing, thereby described ferrule assembly can not be rotated with respect to described housing.

According to another example embodiments of the present utility model, a plurality of projections on described back seat are space degree or degree along the circumferential direction, the angle of during for the end face at the polishing ferrule assembly, regulating described ferrule assembly.

According to another example embodiments of the present utility model, the surface of the rear end of described crimp body forms scraggly rough surface, for the reinforcing element by optical cable, is crimped onto it.

According to another example embodiments of the present utility model, described ferrule assembly also comprises: an encapsulating pipe, described encapsulating pipe is connected on the rear end of described back seat, for the endoporus to lock pin, injects glue, for optical fiber being fixed on to the endoporus of lock pin.

According to another example embodiments of the present utility model, the SC type joints of optical fibre that the described joints of optical fibre are angled physical contact.

According to another example embodiments of the present utility model, the inner shell that described housing is the described SC type joints of optical fibre, the described SC type joints of optical fibre also comprise the external shell be arranged on inner shell.

According to another aspect of the present utility model, a kind of manufacture method of the aforementioned joints of optical fibre is provided, comprise the steps:

S10: ferrule assembly is installed to the first installed position on housing together in company with crimp body, and the end face of ferrule assembly is carried out to non-angular contact polishing, described non-angular contact polishing refers to the end face of ferrule assembly is polished into to the plane vertical with the direction of optical axis; With

S20: ferrule assembly is installed to the second installed position on housing together in company with crimp body, and the end face of ferrule assembly is carried out to angled contact polishing, described angled contact polishing refers to the end face of ferrule assembly is polished into to the dip plane that becomes predetermined angular with the direction of optical axis.

According to another example embodiments of the present utility model, described step S10 also comprises step:

S11: before or after non-angular contact polishing, the angle of regulating described ferrule assembly.

According to another aspect of the present utility model, a kind of manufacture method of the aforementioned joints of optical fibre is provided, comprise the steps:

S100: before being installed on housing by ferrule assembly, in advance the end face of ferrule assembly is carried out to non-angular contact polishing, described non-angular contact polishing refers to the end face of ferrule assembly is polished into to the plane vertical with the direction of optical axis; With

S200: ferrule assembly is installed to the second installed position on housing together in company with crimp body, and the end face of ferrule assembly is carried out to angled contact polishing, described angled contact polishing refers to the end face of ferrule assembly is polished into to the dip plane that becomes predetermined angular with the direction of optical axis.

According to another example embodiments of the present utility model, also comprise step between described step S100 and step S200:

S101: before or after ferrule assembly is installed to the first installed position on housing together in company with crimp body, the angle of regulating described ferrule assembly.

According to another aspect of the present utility model, a kind of assembly method of the aforementioned joints of optical fibre is provided, comprise the steps:

S1000: ferrule assembly is installed to the first installed position on housing together in company with crimp body, and the angle of ferrule assembly is regulated; With

S2000: ferrule assembly is installed to the second installed position on housing together in company with crimp body.

In the utility model, on crimp body, be formed with along its isolated two projections in axial direction front and back, be formed with two corresponding grooves simultaneously on inner housing, when at first the first projection of crimp body front end enters the first groove on inner housing, can carry out the angle of the end surface grinding without the gradient plane and the adjustment fiber stub assembly of ferrule assembly; When the second projection of crimp body back enters the first groove on inner housing, fiber stub can not carry out angular adjustment, now can carry out the grinding of the oblique angle end face of fiber stub assembly.

The joints of optical fibre of the present utility model both can guarantee can select flexibly loose mail or preassembled connector apparatus in the production phase of product, so that adapt to different polishing process and assembly technology; Can regulate as required in process of production the angle of fiber stub again, less insertion loss in assurance itself and interworking; The most important thing is, the loss that the lock pin big angle rotary that can avoid causing when clean connector ends causes thereupon increases, and problem that can not interworking between the APC connector that causes of rotation.Therefore, these series of products not only keep original external structure, and are the high performance optical fiber connectors that flexibility ratio is high, reliability is strong.

By the description of hereinafter with reference to accompanying drawing, the utility model being done, other purpose of the present utility model and advantage will be apparent, and can help that the utility model is had to comprehensive understanding.

The accompanying drawing explanation

Fig. 1 shows the perspective exploded view according to the SC-APC joints of optical fibre of the first example embodiments of the present utility model;

Fig. 2 shows inner housing in Fig. 1 and the enlarged diagram of crimp body;

Fig. 3 shows the schematic diagram when ferrule assembly in Fig. 1, spring are installed to the first installation site in inner housing together with crimp body;

Fig. 4 shows the schematic diagram when ferrule assembly in Fig. 1, spring are installed to the second installation site in inner housing together with crimp body;

Fig. 5 demonstration is installed to shell body schematic diagram before by the inner housing shown in Fig. 4;

Fig. 6 demonstration is installed to the schematic diagram in shell body by the inner housing shown in Fig. 4;

Fig. 7 shows according to the inner housing of the SC-APC joints of optical fibre of the second example embodiments of the present utility model and the enlarged diagram of crimp body;

Fig. 8 shows the schematic diagram when ferrule assembly in Fig. 7, spring are installed to the first installation site in inner housing together with crimp body;

Fig. 9 shows the schematic diagram when ferrule assembly in Fig. 7, spring are installed to the second installation site in inner housing together with crimp body;

Figure 10 shows according to the inner housing of the SC-APC joints of optical fibre of the 3rd example embodiments of the present utility model and the enlarged diagram of crimp body;

Figure 11 shows the schematic diagram when ferrule assembly in Figure 10, spring are installed to the first installation site in inner housing together with crimp body;

Figure 12 shows the schematic diagram when ferrule assembly in Figure 10, spring are installed to the second installation site in inner housing together with crimp body;

Figure 13 has shown a kind of perspective exploded view of the existing SC type joints of optical fibre; With

Figure 14 shows that the ferrule assembly in Figure 13 is assembled into the schematic diagram in inner casing together in company with crimp body.

Embodiment

Below by embodiment, and by reference to the accompanying drawings, the technical solution of the utility model is described in further detail.In instructions, same or analogous drawing reference numeral is indicated same or analogous parts.Following with reference to accompanying drawing, the explanation to the utility model embodiment is intended to overall utility model design of the present utility model is made an explanation, and not should be understood to a kind of restriction of the present utility model.

the first embodiment

Fig. 1 shows the perspective exploded view according to the SC-APC joints of optical fibre of the first example embodiments of the present utility model.

In the embodiment shown in fig. 1, as example describes, still, the utility model is not limited to this, also can be applied to the joints of optical fibre of other type to take the SC-APC joints of optical fibre (the SC type joints of optical fibre with end face of angled physical contact).

As shown in Figure 1, the joints of optical fibre mainly comprise crimp body 100, inner housing 200, ferrule assembly 300, spring 400 and shell body 500.

As shown in Figure 1, the front end of crimp body 100 (towards an end of ferrule assembly 300) forms a cylinder, when assembling optical fiber connector, spring 400 is contained in crimp body 100 and between crimp body 100 and ferrule assembly 300, crimp body 100 is enclosed within on ferrule assembly 300, ferrule assembly 300 is installed in inner housing 200 together in company with crimp body 100, and then, inner housing 200 is installed in shell body 500.

As shown in Figure 1, ferrule assembly 300 mainly comprises lock pin 301 and the back seat 302 that is sleeved on the rear end of lock pin 301.Although not shown, lock pin 301 has endoporus, and optical fiber is fixed in this endoporus, for example, by glue, is fixed in the endoporus of lock pin 301.

Please continue referring to Fig. 1, on the periphery of back seat 302 evenly and compartment of terrain be distributed with a plurality of protruding 303.Although not shown, in inner housing 200, be formed with and a plurality of protruding 303 grooves that coordinate, when spring 400 pushing back seat 302, the projection 303 of back seat 302 engages with the groove in inner housing 200, thereby ferrule assembly 300 can not be rotated with respect to inner housing 200.

Fig. 2 shows inner housing 200 in Fig. 1 and the enlarged diagram of crimp body 100.

As depicted in figs. 1 and 2, be formed with first projection the 101 and second projection 102 on the periphery wall of crimp body 100, first projection the 101 and second projection 102 crimp body 100 axially at a distance of preset distance, simultaneously, be formed with the first groove 201 and the second groove 202 on inner housing 200.

Fig. 3 shows the schematic diagram when ferrule assembly 300 in Fig. 1, spring 400 are installed to the first installation site in inner housing 200 together with crimp body 100.

As shown in Figure 3, when in the first installation site, the first projection 101 on crimp body 100 is snapped in the first groove 201 on inner housing 200, thereby makes crimp body 100 and inner housing 200 be maintained at the first installed position.

In the utility model, when in the first installation site, ferrule assembly 300 can separate with housing 200, and can be with respect to housing 200 rotations.That is to say, when in the first installation site, spring 400 is not squeezed or slightly is squeezed, therefore, projection 303 on the back seat 302 of ferrule assembly 300 do not have reliably with inner housing 200 in fillistered joint be combined, can be easily with inner housing 200 in groove break away from, therefore, ferrule assembly 300 can be with respect to housing 200 rotations, in order to can regulate the angle of ferrule assembly 300.

Fig. 4 shows the schematic diagram when ferrule assembly 300 in Fig. 1, spring 400 are installed to the second installation site in inner housing 200 together with crimp body 100.

As shown in Figure 4, when in the second installation site, the first projection 101 is snapped in the second groove 202, and the second projection 102 is snapped in the first groove 201, thereby makes crimp body 100 and inner housing 200 be maintained at the second installed position.

In the utility model, when in the second installation site, spring 400 is subject to than extruding much larger when the first installation site, therefore, spring 400 is compressed on ferrule assembly 300, make ferrule assembly 300 and inner housing 200 be bonded together reliably, can not be separated from each other, thus can not be with respect to inner housing 200 rotations.

As shown in Figure 2, in a preferred embodiment of the present utility model, first projection the 101 and second projection 102 is the arc convex section of extending along the periphery of crimp body 100.

As shown in Figure 2, in a preferred embodiment of the present utility model, first projection the 101 and second projection 102 crimp body 100 axially on before and after alignment; And the first groove 201 and the second groove 202 inner housing 200 axially on before and after alignment.

As shown in Figure 2, in a preferred embodiment of the present utility model, the circumferential lengths of the first projection 101 is less than the circumferential lengths of the second projection 102; And the width of the first groove 201 is greater than the width of the second groove 202.

As shown in Figure 2, in a preferred embodiment of the present utility model, the first groove 201 and the second groove 202 are interconnected, and make the first projection 101 to enter the second groove 202 from the first groove 201 unobstructedly.

Fig. 5 demonstration is installed to shell body 500 schematic diagram before by the inner housing 200 shown in Fig. 4; Show the inner housing 200 shown in Fig. 4 is installed to the schematic diagram in shell body 500 with Fig. 6.

As shown in Figure 5 and Figure 6, after ferrule assembly 300, spring 400, crimp body 100 are installed to the second installation site of inner housing 200, in whole inner housing 200 is installed to shell body 500, just completed the assembling of the whole SC joints of optical fibre.

As shown in Figure 1, in an example embodiments of the present utility model, on back seat 302 a plurality of protruding 303 be space 60 degree or 90 degree along the circumferential direction, during for the end face at polishing ferrule assembly 300 with the angle of the end face of the angular adjustment ferrule assemblies 300 of 60 degree or 90 degree.

Please continue referring to Fig. 1, the surface of the rear end 103 of crimp body 100 forms scraggly rough surface, for the reinforcing element of optical cable is crimped onto to it, for example, the Kafra fiber of optical cable is crimped onto on the rear end 103 of crimp body 100, be delivered to crimp body 100, inner housing 200 and shell body 500 for the external force that will be applied on optical cable, rather than be delivered on the bare fibre (not shown) of optical cable, thereby prevent from breaking bare fibre.

As shown in Figure 1, in an embodiment of the present utility model, ferrule assembly 300 also comprises an encapsulating pipe 304, encapsulating pipe 304 is connected on the rear end of back seat 302, for to the endoporus of lock pin 301, injecting glue, during glue can be poured in advance the endoporus of lock pin 301 before inserting optical fiber, also can after inserting optical fiber, glue be poured in to the endoporus of lock pin 301 again, when glue is heated while solidifying, optical fiber just is fixed in the endoporus of lock pin 301.

For the SC-APC joints of optical fibre shown in Fig. 1 to Fig. 6, its a kind of manufacture method mainly comprises the steps:

S10: ferrule assembly 300 is installed to together with crimp body 100 to the first installed position on inner housing 200 with spring 400, and the end face of ferrule assembly 300 is carried out to non-angular contact polishing, non-angular contact polishing refers to the end face of ferrule assembly 300 is polished into to the plane vertical with the direction of optical axis; With

S20: ferrule assembly 300 is installed to together with crimp body 100 to the second installed position on inner housing 200 with spring 400, and the end face of ferrule assembly 300 is carried out to angled contact polishing, angled contact polishing refers to the end face of ferrule assembly 300 is polished into to the dip plane that becomes predetermined angular with the direction of optical axis.

In aforementioned manufacture method, step S10 can also comprise step:

S11: before or after non-angular contact polishing, the angle of regulating ferrule assembly 300.

For the SC-APC joints of optical fibre shown in Fig. 1 to Fig. 6, its another kind of manufacture method mainly comprises the steps:

S100: before being installed on inner housing 200 by ferrule assembly 300, in advance the end face of ferrule assembly 300 is carried out to non-angular contact polishing, non-angular contact polishing refers to the end face of ferrule assembly 300 is polished into to the plane vertical with the direction of optical axis; With

S200: ferrule assembly 300 is installed to together with crimp body 100 to the second installed position on inner housing 200 with spring 400, and the end face of ferrule assembly 300 is carried out to angled contact polishing, angled contact polishing refers to the end face of ferrule assembly 300 is polished into to the dip plane that becomes predetermined angular with the direction of optical axis.

In aforementioned manufacture method, between step S100 and step S200, can also comprise step:

S101: before or after ferrule assembly 300 is installed to the first installed position on inner housing 200 together in company with crimp body 100, regulate the angle of ferrule assembly 300.

For the SC-APC joints of optical fibre shown in Fig. 1 to Fig. 6, its assembly method roughly comprises the steps:

S1000: ferrule assembly 300 is installed to together with crimp body 100 to the first installed position on inner housing 200 with spring 400, and the angle of ferrule assembly 300 is regulated; With

S2000: ferrule assembly 300 is installed to together with crimp body 100 to the second installed position on inner housing 200 with spring 400.

the second embodiment

Fig. 7 shows according to the inner housing 200 ' of the SC-APC joints of optical fibre of the second example embodiments of the present utility model and the enlarged diagram of crimp body 100 '.

The SC-APC joints of optical fibre of the second example embodiments shown in Fig. 7 are compared with the SC-APC joints of optical fibre of the first example embodiments shown in Fig. 1 to Fig. 6, and its difference only is the first groove 201 ' on inner housing 200 ' and the structure of the second groove 202 '.

As shown in Figure 7, in the SC-APC of the second example embodiments joints of optical fibre, the first groove 201 ' and the second groove 202 ' are spaced from each other, and make the first projection 101 ' need to overcome predetermined interference drag and could enter the second groove 202 ' from the first groove 201 '.

Fig. 8 shows the schematic diagram when ferrule assembly in Fig. 7 (not indicating), spring (not indicating) and crimp body 100 ' are installed to the first installation site in inner housing 200 ' together.

As shown in Figure 8, when in the first installation site, the first projection 101 ' on crimp body 100 ' is snapped in the first groove 201 ' on inner housing 200 ', thereby makes crimp body 100 ' and inner housing 200 ' be maintained at the first installed position.

Fig. 9 shows the schematic diagram when ferrule assembly in Fig. 7, spring are installed to the second installation site in inner housing 200 ' together with crimp body 100 '.

As shown in Figure 9, when in the second installation site, the first projection 101 ' overcomes predetermined interference drag and enters in the second groove 202 ' and be snapped in the second groove 202 ', and the second projection 102 ' is snapped in the first groove 201 ', thereby make crimp body 100 ' and inner housing 200 ' be maintained at the second installed position.

the 3rd embodiment

Figure 10 shows the inner housing 200 according to the SC-APC joints of optical fibre of the 3rd example embodiments of the present utility model " and crimp body 100 " enlarged diagram.

The SC-APC joints of optical fibre of the 3rd example embodiments shown in Figure 10 are compared with the SC-APC joints of optical fibre of the first example embodiments shown in Fig. 1 to Fig. 6, and its difference only is the structure of the first projection and the second projection, the first groove and the second groove.

As shown in figure 10, in crimp body 100 " periphery wall on be formed with the first projection 101 " and the second projection 102 ", the first projection 101 " and the second projection 102 " in crimp body 100 " axially upper at a distance of preset distance, and upwards mutually stagger in week.

Please continue referring to Figure 10, at inner housing 200 " on be formed with the first groove 201 " and the second groove 202 "; the first groove 201 " and the second groove 202 " at inner housing 200 " periphery on mutually stagger, and the first projection 101 " can be at the first groove 201 " in slide into the second position from the first position.In the example depicted in fig. 10, the first groove 201 " be one at inner housing 200 " the notch of the upwardly extending strip of axle, therefore, the first projection 101 " can be at the first groove 201 " in slide into the second position from the first position.

Figure 11 shows the ferrule assembly in Figure 10 (indicating), spring (indicating) and crimp body 100 " be installed to together inner housing 200 " in the first installation site the time schematic diagram.

As shown in figure 11, when in the first installation site, the first projection 101 " be snapped into the first groove 201 " in the first position, thereby make crimp body 100 " and inner housing 200 " be maintained at the first installed position.

Figure 12 shows the ferrule assembly in Figure 10, spring and crimp body 100 " together be installed to inner housing 200 " in the second installation site the time schematic diagram.

As shown in figure 12, when in the second installation site, the first projection 101 " slide into the first groove 201 " in the second position, and the second projection 102 " be snapped into the second groove 202 " in, thereby make crimp body 100 " and inner housing 200 " be maintained at the second installed position.

In the 3rd embodiment shown in Figure 10 to Figure 12, the first projection 101 " and the second projection 102 " be along crimp body 100 " the periphery arc convex section of extending.The first projection 101 " circumferential lengths be less than the second projection 102 " circumferential lengths, and the first groove 201 " width be greater than the second groove 202 " width.

In the aforementioned first to the 3rd embodiment of the present utility model, on crimp body, be formed with along its isolated two projections in axial direction front and back, be formed with two corresponding grooves simultaneously on inner housing, when at first the first projection of crimp body front end enters the first groove on inner housing, can carry out the angle of the end surface grinding without the gradient plane and the adjustment fiber stub assembly of ferrule assembly; When the second projection of crimp body back enters the first groove on inner housing, fiber stub can not carry out angular adjustment, now can carry out the grinding of the oblique angle end face of fiber stub assembly.Therefore, the joints of optical fibre of the present utility model can be applied to the different phase in joints of optical fibre production neatly,, the joints of optical fibre of the present utility model both can guarantee can select flexibly loose mail or preassembled connector apparatus in the production phase of product, so that adapt to different polishing process and assembly technology; Can regulate as required in process of production the angle of fiber stub again, less insertion loss in assurance itself and interworking; The most important thing is, the loss that the lock pin big angle rotary that can avoid causing when clean connector ends causes thereupon increases, and problem that can not interworking between the APC connector that causes of rotation.Therefore, these series of products not only keep original external structure, and are the high performance optical fiber connectors that flexibility ratio is high, reliability is strong.

The aforementioned first biconvex to the 3rd embodiment rises with double recess can be applied to joints of optical fibre loose mail or preassembled joints of optical fibre device, is applicable to the optical cable of 0.9mm/2mm/3mm.This structure can guarantee that the deflection of 60 degree or 90 degree and multiple thereof can not occur client's fiber stub angle when clean fiber end face.Whether this structure can also be according to needing the angle of regulating ferrule assembly to select flexibly corresponding with it polishing and assembly technology.

It will be appreciated by those skilled in the art that, embodiment described above is exemplary, and those skilled in the art can make improvements, the structure described in various embodiment in the situation that not the conflict aspect recurring structure or principle can carry out independent assortment.

Although by reference to the accompanying drawings the utility model is illustrated, in accompanying drawing, disclosed embodiment is intended to the utility model preferred implementation is carried out to exemplary illustration, and can not be interpreted as a kind of restriction of the present utility model.

Although some embodiment of this overall utility model design are shown and explanation, those skilled in the art will appreciate that, in the situation that do not deviate from principle and the spirit of this overall utility model design, can make a change these embodiment, scope of the present utility model limits with claim and their equivalent.

It should be noted that word " comprises " does not get rid of other element or step, and word " " or " one " do not get rid of a plurality of.In addition, any element numbers of claim should not be construed as restriction scope of the present utility model.

Claims (18)

1. the joints of optical fibre comprise:

Ferrule assembly (300); With

Crimp body (100), be enclosed within on described ferrule assembly (300);

Housing (200), described ferrule assembly (300) is installed in described housing (200) together in company with described crimp body (100),

It is characterized in that:

Described crimp body (100) and described housing (200) are configured to mutually remain on the first installation site and the second installation site,

When in the first installation site, described ferrule assembly (300) can separate with described housing (200), and can rotate with respect to described housing (200),

When in the second installation site, described ferrule assembly (300) engages with described housing (200), can not rotate with respect to described housing (200).

2. the joints of optical fibre according to claim 1, is characterized in that, also comprises:

Spring (400), be contained in crimp body (100) and be positioned at described crimp body (100) and described ferrule assembly (300) between,

When in the second installation site, it is upper that described spring (400) is compressed in described ferrule assembly (300), makes described ferrule assembly (300) engage with described housing (200).

3. the joints of optical fibre according to claim 2, is characterized in that,

Be formed with the first projection (101) and the second projection (102) on the periphery wall of described crimp body (100), described the first projection (101) and described the second projection (102) are axially upper at a distance of preset distance described crimp body (100);

Be formed with the first groove (201) and the second groove (202) on described housing (200),

When in the first installation site, described the first projection (101) is snapped in described the first groove (201), thereby makes described crimp body (100) and described housing (200) be maintained at the first installed position;

When in the second installation site, described the first projection (101) is snapped in described the second groove (202), and described the second projection (102) is snapped in described the first groove (201), thereby make described crimp body (100) and described housing (200) be maintained at the second installed position.

4. the joints of optical fibre according to claim 3, is characterized in that,

Described the first projection (101) and described the second projection (102) are the arc convex section of extending along the periphery of described crimp body (100).

5. the joints of optical fibre according to claim 4, is characterized in that,

Described the first projection (101) and described the second projection (102) are in the axially upper front and back alignment of described crimp body (100); And

Described the first groove (201) and described the second groove (202) are in the axially upper front and back alignment of described housing (200).

6. the joints of optical fibre according to claim 5, is characterized in that,

The circumferential lengths of described the first projection (101) is less than the circumferential lengths of described the second projection (102); And

The width of described the first groove (201) is greater than the width of described the second groove (202).

7. the joints of optical fibre according to claim 6, is characterized in that,

Described the first groove (201) and described the second groove (202) are interconnected, and make described the first projection (101) to enter described the second groove (202) from described the first groove (201) unobstructedly.

8. the joints of optical fibre according to claim 6, is characterized in that,

Described the first groove (201 ') and described the second groove (202 ') are spaced from each other, and make described the first projection (101 ') need to overcome predetermined interference drag and could enter described the second groove (202 ') from described the first groove (201 ').

9. the joints of optical fibre according to claim 2, is characterized in that,

Be formed with the first projection (101 ") and the second projection (102 ") on the periphery wall of described crimp body (100 "); described the first projection (101 ") and described the second projection (102 ") are axially upper at a distance of preset distance described crimp body (100 "), and upwards mutually stagger in week;

Be formed with the first groove (201 ") and the second groove (202 ") on described housing (200), described the first groove (201 ") and described the second groove (202 ") mutually stagger on the periphery of described housing (200 "); and described the first projection (101 ") can slide into the second position from the first position in described the first groove (201 ")

When in the first installation site, described the first projection (101 ") is snapped into the first position in described the first groove (201 "), thereby makes described crimp body (100 ") and described housing (200 ") be maintained at the first installed position;

When in the second installation site, described the first projection (101 ") slides into the second position in described the first groove (201 "), and described the second projection (102 ") is snapped in described the second groove (202 "), thereby make described crimp body (100 ") and described housing (200 ") be maintained at the second installed position.

10. the joints of optical fibre according to claim 9, is characterized in that,

Described the first projection (101 ") and described the second projection (102 ") are the arc convex section of extending along the periphery of described crimp body (100 ").

11. the joints of optical fibre according to claim 10, is characterized in that,

The circumferential lengths of described the first projection (101 ") is less than the circumferential lengths of described the second projection (102 "); And

The width of described the first groove (201 ") is greater than the width of described the second groove (202 ").

12. according to the described joints of optical fibre of any one in claim 1-11, it is characterized in that, described ferrule assembly (300) comprising:

Lock pin (301), have endoporus, and optical fiber is fixed in this endoporus; With

Back seat (302), be sleeved on the rear end of described lock pin (301).

13. the joints of optical fibre according to claim 12, is characterized in that,

On the periphery of described back seat (302) evenly and compartment of terrain be distributed with a plurality of projections (303); And

Be formed with the groove coordinated with described a plurality of projections (303) in described housing (200), when spring (400) pushing back seat (302), the projection (303) of described back seat (302) engages with the groove in described housing (200), thereby described ferrule assembly (300) can not be rotated with respect to described housing (200).

14. the joints of optical fibre according to claim 13, is characterized in that,

A plurality of projections (303) on described back seat (302) are space 60 degree or 90 degree along the circumferential direction, the angle of during for the end face at polishing ferrule assembly (300), regulating described ferrule assembly (300).

15. the joints of optical fibre according to claim 14, is characterized in that,

The surface of the rear end (103) of described crimp body (100) forms scraggly rough surface, for the reinforcing element by optical cable, is crimped onto it.

16. the joints of optical fibre according to claim 15, is characterized in that, described ferrule assembly (300) also comprises:

An encapsulating pipe (304), described encapsulating pipe (304) is connected on the rear end of described back seat (302), for the endoporus to lock pin (301), injects glue, for optical fiber being fixed on to the endoporus of lock pin (301).

17. the joints of optical fibre according to claim 16, is characterized in that, the SC type joints of optical fibre that the described joints of optical fibre are angled physical contact.

18. the joints of optical fibre according to claim 17, is characterized in that,

The inner shell that described housing (200) is the described SC type joints of optical fibre, the described SC type joints of optical fibre also comprise the external shell (500) be arranged on inner shell.

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