JP2000098183A - Optical connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical connector which is easy to assemble and eliminates a possibility that a housing is disassembled by a tensile external force. An optical connector ferrule (3) is provided on a casing (1).
Is inserted, the push rod 22 is pushed in from the rear to assemble the optical connector. The push rod 2 is provided with a pair of locking claws 2a, and the locked projection 2b and the first receiving portion 2
c, a second receiving portion 2d is formed. A locking recess 1b is formed in the casing. When the push rod 2 is pushed in, the pair of locking claws are inserted into the casing while being elastically deformed inward to each other. When the locked projection reaches the locking recess, the elastic deformation is released, and the locked projection is released. The projection is locked in the locking recess, and the rear ring 4 of the coil spring 4 is interposed between the pair of locking claws.
a to prevent the locking claw from being deformed inward again.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical connector used in an optical connection technology in the field of optical communication, and more particularly to an optical connector having a housing for housing an optical connector ferrule and a spring member for pressing the optical connector ferrule from behind. It is about.

[0002]

2. Description of the Related Art In many cases, an optical connector used in an application having a relatively large number of attachments and detachments, such as in a communication device, has a plug housing having a push-pull mechanism and is connected through a connector adapter.

FIG. 7 schematically shows an example of a conventional push-pull type multi-core optical connector. FIG. 7 (A) is a perspective view at the time of non-connection, and FIG. 7 (B) is a perspective view at the time of connection. . In the figure, 1
Reference numerals 1 and 12 are optical connector plugs, 11a and 12a are optical fiber cords, 11b is a guide pin, 11c is an optical fiber, and 13 is a coupling adapter.

As shown in FIG. 7A, two optical connector plugs 11 and 12 are inserted from both sides of a coupling adapter 13 and end faces are connected to each other for connection. The end faces of the two optical connector plugs 11 and 12 are abutted by a guide pin 11 b provided on the optical connector plug 11.
The optical fiber is inserted into a guide pin hole (not shown) provided in the optical connector plug 12 to perform positioning, and optical connection between the optical fibers arranged on the end face is performed. FIG.
(B) shows the coupling state of the two optical connector plugs 11 and 12.

In such a push-pull type optical connector, generally, an optical fiber fixing part called an optical connector ferrule is designed to be axially pressed by a built-in spring member. The optical connector housing has a structure in which a ferrule, a spring member, and the like are inserted into a casing called an insertion guide, and then a member called a push rod is fitted from the rear to apply a pressing force to the spring member to hold it. Generally, the insertion guide and the push rod are manufactured by low-cost, mass-producible plastic molding, and the insertion guide and the push rod are fitted with a so-called killing structure using elastic deformation of the plastic. Often.

[0006] For example, an optical connector cited as a reference in JIS C5982 also has a mating structure using a push rod. In the case of using such a mating structure, the locking claw of the push rod needs to be easily elastically deformed by the hooking dimension of the locking claw at the time of insertion. A seemingly contradictory characteristic is required that a locked hook is not easily deformed again. When such an optical connector is connected to an optical fiber cord including a tensile strength member, the tensile strength member is usually fixed by a push rod, but is pulled to such an optical fiber cord with an optical connector. If you apply force,
This pulling force acts on the pawl to give a rotational moment in the direction of releasing the connection about the edge of the hook. Therefore, when the pulling force exceeds a certain limit, the locking claw is deformed inward by the above-mentioned rotational moment,
In the worst case, there is a concern that the push rod will come off. Therefore, when it is desired to further increase the tensile strength, means for countering inward re-deformation is required.

As means for countering such stress in the direction of re-deformation, the hooks of the locking claws are formed at acute angles to each other,
It is conceivable that the pulling force of the push rod acts in the direction to push and open the claws, but in small parts such as optical connectors,
Due to the design, the catching amount of the locking claw can be as small as 0.5 mm or less at most, and the above effect increases as the acute angle increases, but the strength of the sharp edge weakens. Therefore, it is difficult to sufficiently function with plastic parts.

[0008]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to provide an optical connector which is easy to assemble and eliminates the possibility that the housing will be disassembled by an external tensile force. Things.

[0009]

According to a first aspect of the present invention, there is provided an optical connector having a housing for housing therein an optical connector ferrule and a spring member for pressing the optical connector ferrule from behind. The housing includes at least a first member that houses the optical connector ferrule in a floating state, and a second member that is housed in the first member while the spring member is pressed. Is provided with a pair of locking claws having locked projections on the outside, and the first member is provided with locking recesses for fitting the pair of locking claws from inside. The pair of locking claws are inserted into the first member while being elastically deformed inward to each other, and when the locked projection reaches the locking recess, the elastic deformation is released and the locking claw is released. A locking projection is locked in the locking recess. Wherein between a pair of locking claws, and is characterized in that the locking pawl is so enters the aggregate to prevent re-deformed inward.

According to a second aspect of the present invention, in the optical connector according to the first aspect, the aggregate is the spring member itself or a spacer member arranged at a rear portion of the spring member. The spring member does not receive a compressive force until the pair of locking claws elastically deform, and then the first member elastically deforms inward as the second member is pushed into the first member. The first receiving portion provided on the pair of locking claws comes into contact with the aggregate and receives a compressive force.
At the time when the elastic deformation is released, the inner dimensions of the first receiving portion are widened and the contact between the first receiving portion and the aggregate is released, and the aggregate is compressed by a compression reaction force of a spring member. The aggregate enters the inside of the first receiving portion, and the aggregate is supported by a second receiving portion provided behind and inside the first receiving portion.

According to a third aspect of the present invention, in the optical connector according to the second aspect, the sum of the dimensions of the locked projections on both sides of the locking claw is equal to the inner dimension of the second receiving portion. It is characterized in that it is larger than the difference from the outer size of the aggregate.

[0012]

1 to 6 are for explaining an example of an embodiment of an optical connector according to the present invention.
FIG. 5 is a sectional view for explaining the internal structure together with the order of assembly, and FIG. 6 is an enlarged sectional view of a main part. In the figure, 1
Is a casing, 1a is a housing space, 1b is a locking concave portion, 2 is a push rod, 2a is a locking claw, 2b is a locked convex portion, and 2c is a first
2d is a second receiving portion, 3 is an optical connector ferrule, 4 is a spring member, and 5 is a multi-core optical fiber tape. The illustration of the retaining portion of the strength member is omitted in the drawing.

FIG. 1 shows a state in which an optical connector ferrule 3 attached to a multi-core optical fiber tape 5 is inserted into a casing 1. First, the configuration of each unit will be described. The casing 1 is a first member, and the push rod 2 is a second member.
A housing is configured. As will be described later, the push rod 2 is inserted from the rear of the casing 1 and engages with the casing to be integrated. A housing space 1a capable of housing the optical connector ferrule 3 in a floating state is prepared inside the casing 1, and a push rod 2 is inserted from the rear of the housing space 1a. A spring member 4 is arranged between the push rod 2 and the optical connector ferrule 3. In this embodiment, the spring member 4 uses a coil spring. The push rod 2 is provided with locking claws 2a on both sides in front of the locking rod 2a, a locked convex portion 2b outside the locking claws 2a, a first receiving portion 2c inside the distal end portion, and then a second receiving portion 2c. Receiving part 2d
Are formed. The locked convex portion 2b is provided at a position where it engages with the locking concave portion 1b of the casing 1. The push rod 2 is pushed in from this state.

FIG. 2 shows a state in which the tip of the locking claw 2a is inserted. The space on both sides of the tip of the locking claw 2a is formed to be smaller than or substantially equal to the space between the inner walls of the casing 1. In this state, the locked projection 2b starts to abut against the inner wall of the casing 1, and when the push rod 2 is further pushed in from this point, the locking claw 2a starts to be deformed inward by the inner wall of the casing 1.

FIG. 3 shows a state in which the locking claw 2a is maximally deformed. The rear ring 4a of the spring member 4 enters inside the tip of the locking claw 2a. When the push rod 2 is further pushed in, FIG.
As shown in FIG. 5, the first receiving portion 2c of the locking claw 2a abuts on the rear ring 4a of the spring member 4, and pushes the spring member 4 in the compression direction.

Further, when the push rod 2 is pushed in, as shown in FIG.
b, and at the same time, the interval between the first receiving portions 2c is widened, so that the rear ring 4a of the spring member 4 abuts from the first receiving portion 2c to the second receiving portion 2d. Become. In this state, the spring member 4 is located between the second receiving portions 2d.
The rear ring 4a enters and the rear ring 4a becomes an aggregate,
It serves as a refill bar to prevent the locking claws 2a from falling inward. In this state, since the compressive stress is applied to the spring member 4, the spring member 4 does not escape from between the second receiving portions 2d.

A preferred example between the dimensions of the locking claw 2a, the first receiving portion 2c, and the rear ring 4a of the spring member 4 will be described. In this embodiment, the sum of the dimensions A of the locked projections 2b formed on both sides of the locking claw 2a is the inner dimension B between the second receiving portions 2d and the rear ring 4a, that is, the aggregate of the aggregate. It is made larger than the difference from the outer dimension C. As a result, the aggregate is transferred to the second receiving portion 2
This is because if a large pull-out force is applied at the time when the optical connector is inserted into d and assembly of the optical connector is completed, the push rod 2 may come off. Further, the dimension is set so that the rear ring 4a of the spring member 4 does not enter between the first receiving portions 2c from the state of FIG. 2 to immediately before the state of FIG.
To this end, the space between the first receiving portion 2c and the portion where the front end of the spring member 4 abuts (the rear portion of the optical connector ferrule 3 in this figure) is sufficient until the state of FIG. It is necessary to keep the spring member 4 in a state where no compressive stress is applied. When this condition is compromised, FIG.
Before the state shown in FIG. 3 changes to the state shown in FIG. 3, the rear ring 4a serves as a catching rod, and the push rod 2 cannot be inserted. Further, in order to prevent the rear ring 4a from entering between the first receiving portions 2c during the transition from the state shown in FIG. 2 to the state shown in FIG. By bonding it to the back of 3
A method for preventing the spring member 4 from freely moving,
When the push rod 2 is inserted, a method is effective in which the optical connector ferrule 3 faces downward and the spring member 4 is positioned on the optical connector ferrule 3 side using gravity.

In this embodiment, the rear end of the spring member 4 is used as the aggregate as it is.
The and the aggregate need not be the same member, and another member such as a spacer member may be disposed at the rear of the spring member 4 and may be used as the aggregate. Further, the spring member 4 is not limited to a coil spring, and a spring member having an appropriate shape can be used.

Further, in the above-described embodiment, the case of the multi-core optical connector has been described. However, it is needless to say that the present invention can be similarly applied to the case of a single-core optical connector.

[0020]

As is apparent from the above description, according to the present invention, in the process of fitting the locking claw of the push rod, the locking claw can be deformed inward, and when the fitting is completed, By putting the aggregate between the locking claws as a means to counter the inward re-deformation stress acting on the locking claw, and by using a so-called refill structure, if the strength of the aggregate is sufficient,
The locking claw is not deformed again after the insertion of the push rod, and there is an effect of eliminating the possibility that the housing once assembled is disassembled by a tensile external force.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view for explaining an example of an embodiment of an optical connector of the present invention and showing an internal structure in one step of an assembling order.

FIG. 2 is a cross-sectional view for explaining an example of the embodiment of the optical connector of the present invention and showing an internal structure in one step of an assembling order.

FIG. 3 is a cross-sectional view for explaining an example of the embodiment of the optical connector of the present invention and showing an internal structure in one step of an assembling order.

FIG. 4 is a cross-sectional view illustrating an example of an embodiment of an optical connector according to the present invention and illustrating an internal structure in one step of an assembly order.

FIG. 5 is a cross-sectional view illustrating an internal structure of an optical connector according to an embodiment of the present invention in one step of an assembling sequence.

FIG. 6 is an enlarged sectional view of a main part.

7A and 7B schematically show an example of a conventional push-pull type multi-fiber optical connector. FIG.
(B) is a perspective view at the time of coupling.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Casing, 1a ... Housing space, 1b ... Locking concave part, 2
... push rod, 2a ... locking claw, 2b ... locked convex part, 2c ... first receiving part, 2d ... second receiving part, 3 ... optical connector ferrule, 4 ... spring member, 4a ... rear ring, 5. Multi-core optical fiber cord.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Norihiro Yokomachi 1 Tayacho, Sakae-ku, Yokohama-shi, Kanagawa Prefecture Inside the Yokohama Works, Sumitomo Electric Industries, Ltd. Sumitomo Electric Industries, Ltd. Yokohama Works F-term (reference) 2H036 JA02 QA02 QA11 QA32

Claims (3)

[Claims] 1. An optical connector in which an optical connector ferrule and a spring member for pressing the optical connector ferrule from behind are housed in a housing, wherein the housing of the optical connector has at least the optical connector ferrule in a floating state. A first member housed in the first member and a second member housed in the first member in a state where the spring member is pressed.
The second member is provided with a pair of locking claws having a convex portion to be locked on the outside, and the pair of locking claws is fitted on the first member from the inside. And a pair of locking claws are inserted into the first member while being elastically deformed inward to each other, and when the locked projection reaches the locking recess, Elastic deformation is released, the locked projections are locked in the locking recesses, and an aggregate is provided between the pair of locking claws to prevent the locking claws from being deformed inward again. An optical connector characterized by being inserted. 2. The aggregate is the spring member itself or a spacer member disposed at a rear portion of the spring member, and the spring member is used until the pair of locking claws elastically deform. Are not subjected to a compressive force, and as the second member is subsequently pushed into the first member, the first receiving portion and the aggregate provided on the pair of locking claws elastically deformed inward each other. Abuts and receives a compressive force, and further, at the time when the elastic deformation is released, the inner dimension of the first receiving portion expands and the contact between the first receiving portion and the aggregate is released, Due to the compression reaction force of the spring member, the aggregate enters the inside of the first receiving portion, and the aggregate is supported by the second receiving portion provided behind and inside the first receiving portion. The optical connector according to claim 1, wherein: 3. The sum of the dimensions of the locked projections on both sides of the locking claw is larger than the difference between the inner size of the second receiving portion and the outer size of the aggregate. The optical connector according to claim 2.