JPH0784152A - Optical connector - Google Patents

Abstract

PURPOSE:To provide an optical connector which is miniaturized and is excellent in connecting workability. CONSTITUTION:A 1st optical connector plug 8 is constituted of a 1st ferrule 2 holding a 1st optical fiber 1 and having plural guide pin holes 2a which a guide pin 5 pierces, a fixing member 6 holding one end of the guide pin 5, the guide pin 5 which pierces the guide pin hole 2a of the 1st ferrule 2, whose one end is held by the member 6 and which has a constriction part 5b at the other end, and a spring 7. A 2nd optical connector plug 10 is constituted of a 2nd ferrule 4 holding the 2nd optical fiber 3 and having plural guide pin holes 4a which the guide pin 5 pierces, and a locking leaf spring 9 having a locking hole 9c engaged with the constriction part 5b of the guide pin 5 piercing the guide pin hole 4a. The guide pin 5 is inserted in the guide pin hole 4a of the 2nd ferrule 4 and engaged with the locking hole 9c of the spring 9.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical connector in which first and second optical fibers respectively held by a pair of optical connector plugs are optically coupled to each other in a detachable state.

[0002]

2. Description of the Related Art FIG. 3 shows a conventional guide pin coupling type multi-fiber optical connector. Optical connector plugs 01A and 01B
Has two guide pin holes 02A and 02B penetrating in the optical fiber axial direction, and the guide pin 03 is inserted into these guide pin holes 02A and 02B to obtain the first and second optical fibers 04A. End face 05A in which the end faces of and 04B are respectively positioned and arranged
The optical fibers 04A and 04B are optically coupled by abutting the optical fibers 04A and 05B. It should be noted that the pair of optical connectors 01 coupled in this way
A and 01B have leaf spring parts 07 on both ends of the plate member 06.
It is designed to be sandwiched and stably held by a coupling clip 08 provided with.

In this case, the first optical connector plug (first ferrule) 01A holding the first optical fiber 04A.
And the second optical connector plug (second ferrule) 01B for holding the second optical fiber 04B are the same shape members that do not distinguish male and female, and are positioned and coupled by the two guide pins 03, and then the coupling clip. It is necessary to add 08 and press between both plugs to stabilize the coupled state.

Next, another conventional example is shown in FIGS. These are called plug-in type (or push-on type), which does not require the above-mentioned coupling clip, but instead allows the adapter to be interposed between both plugs, and the recess provided in the adapter and the plug. By engaging the convex portions with each other, the end faces of both plugs are held in a state of being pressed against each other in a pressed state.

The optical connector shown in FIG.
No. 226715, in which (A) is a sectional view showing a state in which optical connector plugs are coupled to each other;
(B) is a cross-sectional view of the connector plug. As shown in these drawings, a ferrule 01 having an optical fiber fixed thereto.
An optical connector plug 013 is configured by fixing 1 to a housing 012 having upper and lower arm portions 012a, while an adapter 014 is formed with an insertion portion into which the optical connector plug 013 can be inserted from both sides. Then, the optical connector plugs 013 are inserted into the insertion portions on both sides of the adapter 014, and the convex portion 012b of the arm portion 012a and the concave portion 014a of the adapter 014 are engaged with each other to hold the end faces of the ferrule 011 in abutment with each other. Is able to.

The optical connector shown in FIG.
No. 61713 is disclosed. As shown in the figure, an optical connector plug 023 is configured by fixing a ferrule 021 to which an optical fiber is fixed to a housing 022 having recesses 022a at the top and bottom, while an optical connector is provided on both sides of the adapter 024. An insertion portion into which the plug 023 can be inserted is formed, and an arm portion 024a is formed inside this insertion portion. And the adapter 02
In a state where the end faces of the ferrule 021 are butted against each other by inserting the optical connector plugs 023 into the insertion parts on both sides of 4 and engaging the concave portion 022a with the pawl portion 024b formed at the tip of the arm portion 024a of the adapter 024. It can be held.

[0007]

The optical connector shown in FIG. 3 is extremely simple and small in size, and is effective when arranging in high density in a narrow space. However, there is a problem in workability when connecting the optical connectors, and there is a problem that it takes time and effort to attach a connecting clip using a jig after the optical connector plugs are butted against each other.

On the other hand, in FIGS. 4 and 5, since the optical connector can be attached and detached only by inserting and removing the plug into and from the adapter, the connecting workability is good. However, since it is necessary to provide a concave or convex structure of the adapter, the mechanism becomes complicated and it is not suitable for miniaturization.

In view of such circumstances, an object of the present invention is to
An object of the present invention is to provide an optical connector that is small and has excellent workability in coupling.

[0010]

An optical connector according to the present invention which achieves the above object comprises a pair of optical connector plugs respectively holding a first optical fiber and a second optical fiber. Is an optical connector that optically couples the first and second optical fibers with each other by positioning and connecting the two using at least two guide pins, wherein the first optical connector plug includes the first optical fiber. A first ferrule which holds and has a plurality of guide pin holes through which the guide pin passes, and a fixing member which is on the rear end side of the first ferrule and holds one end of the guide pin,
A guide pin that penetrates through the guide pin hole of the first ferrule and has one end thereof held by the fixing member and has a constricted portion at the other end, and is interposed between the first ferrule and the fixing member. And a second ferrule having a plurality of guide pin holes for holding the second optical fiber and having the guide pins passing therethrough, and a second ferrule after the second ferrule. The guide pin penetrates through the guide pin hole of the second ferrule, and the guide pin penetrates through the guide pin hole in the vicinity of the end face. The spring biases the first ferrule with respect to the second ferrule when engaged with the locking portion of the locking member.

In particular, the locking member is an L-shaped locking leaf spring whose base end is fixed to both side surfaces of the second ferrule, and the locking portion is attached to the tip end of the leaf spring. It is a locking hole formed and through which the guide pin can pass, and when the locking leaf spring is not elastically deformed, the peripheral edge of the locking hole is a part of the opening of the guide pin hole of the second ferrule. Is preferably closed so that the locking plate spring moves in a direction substantially orthogonal to the axial direction of the guide pin hole of the second ferrule by elastic deformation of the locking plate spring.

Further, by gripping both side surfaces of the second connector plug, the locking leaf spring is elastically deformed, and the locking hole and the opening of the guide pin hole of the second ferrule substantially face each other. Then, after the other end of the guide pin is passed through the locking hole, the holding state of the locking leaf spring is released so that the locking hole and the necked portion of the guide pin engage with each other. Preferably.

[0013]

The operation of the optical connector structure according to the present invention will be summarized below.

1. The second optical connector plug has a structure in which a locking member is attached to the second ferrule, and a guide pin fixed to the first optical connector plug is provided with a constricted portion. By engaging the locking portion of the locking member with the constricted portion of the guide pin, the pressing force acting between the coupling end faces of the first optical connector plug and the second optical connector plug can be held. . At this time, the spring provided between the fixing member and the first ferrule causes the first
The ferrule is pressurized in the direction of the second ferrule to ensure optical coupling.

2. The pressing force between the two held plugs is received by the guide pin in the region sandwiched by the fixing member of the first optical connector plug and the locking member of the second optical connector plug. . Since this force is a tensile force in the axial direction of the guide pin, there is no concern about rigidity, and even a thin guide pin can hold a large pressing force, which contributes to downsizing of the entire plug.

3. When a locking plate spring is used as the locking member to be locked in the constricted portion of the guide pin, the peripheral edge of the locking hole of the locking plate spring is located at the rear end surface of the second ferrule and the guide pin. It will be in a state of being sandwiched between the protruding portion adjacent to the constricted portion, but the force acting on the locking leaf spring at this time is a shearing force in the thickness direction of the plate material, and is different from the spring elastic deformation direction of the locking leaf spring. The directions are substantially orthogonal. Therefore, it is not necessary to select the wall thickness in consideration of the strength of the locking leaf spring, and it is possible to select the thin locking leaf spring regardless of the pressing force between the plugs and suppress the force required for spring deformation. This facilitates the workability in coupling the optical connectors and improves the coupling workability.

4. When holding the second optical connector plug, by holding the locking plate spring at the same time, the holding of the optical connector and the deformation of the locking plate spring can be performed in one operation. The work process can be simplified.

[0018]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 shows an optical connector according to an embodiment of the present invention. (A) is a cross-sectional view before coupling, (B).
Shows a cross-sectional view of the combined state. As shown in the figure, the first ferrule 2 holding the first fiber 1 and the second ferrule 4 holding the second fiber 3 have a common structure. That is, each of the first and second ferrules 2 and 4 is provided with two guide pin holes 2a and 4a penetrating each in the fiber axial direction, and these first and second ferrules 2 and 4 are provided. The first and second optical fibers 1 and 3 can be optically coupled by inserting the guide pin 5 into the guide pin holes 2a and 4a and bringing the coupling end faces into close contact with each other while positioning. Here, each of the first and second optical fibers 1 and 3 has two guide pin holes 2a and 4a.
In the present embodiment, one optical fiber is end-polished and fixed. The number of optical fibers may be plural, and 2 or 4 at a constant pitch (for example, 0.25 mm).
It may be arranged in a book, eight, or the like. This technique has already been applied to the conventional technique shown in FIG. The outer dimensions of the first and second ferrules 2 and 4 are 4 mm x 2.5 mm x 8
mm, made by molding with epoxy resin,
The guide pin 5 is a super steel pin and has an outer diameter of 0.7
mm.

On the rear end side of the first ferrule 2, a fixing member 6 for holding one end of the guide pin 5 is arranged.
The coil spring 7 is held between the first ferrule 2 and the first ferrule 2 in a state of being penetrated by the two guide pins 5, respectively, and thereby the first optical connector plug 8 is formed. More specifically, the fixing member 6 has a guide pin 5
Is provided with a recess 6a for holding one end of
A protrusion 6b protruding inward in the radial direction is provided in a, while a first constricted portion 5a is provided at one end.
As a result, one end of the guide pin 5 is press-fitted into the recess 6a to engage the protrusion 6b with the first constricted portion 5a, whereby the guide pin 5 is held by the fixing member 6. The two guide pins 5 held by the fixing member 6 are inserted into the guide pin holes 2a of the first ferrule 2 with the coil spring 7 interposed therebetween. Further, the other end of the guide pin 5 has a second neck portion 5
b is provided, and the small diameter dimension of the constricted portion 5b is φ0.
It is 4 mm.

On the other hand, the second ferrule 4 is provided with two locking leaf springs 9 as locking members, whereby a second optical connector plug 10 is constituted. More specifically, the locking leaf spring 9 is bent in a substantially L shape along the side surface (both sides in the arrangement direction of the guide pin holes 2a) and the rear end surface of the second ferrule 4, and the base end portion is a side surface. A spring portion 9a that is fixed to the coupling end face side and that separates from the side face as it extends to the side face rear end face side, and a lock that bends from this spring portion 9a along the rear end face and faces the opening of the guide pin hole 2a. And part 9b. The locking portion 9b is formed with a locking hole 9c having a size through which the tip end of the guide pin 5 can penetrate. When the spring portion 9a is not elastically deformed, the peripheral edge of the locking hole 9c is a guide pin. Although a part of the inside of the hole 2a is blocked, when the spring portion 9b on the rear end face side of the second ferrule 4 is elastically deformed by being pressed toward the ferrule, the locking hole 9c and the guide pin hole 2a are You can match.

The locking leaf spring 9 can be obtained by press-molding stainless steel having a wall thickness of 0.2 mm. The locking leaf spring 9 is fixed in such a manner that a protrusion (not shown) provided at the base end portion is fitted into a groove (not shown) of the first ferrule 2, and the base end portion is further fixed with an adhesive as reinforcement. To be done. Further, the locking leaf spring 9 easily elastically deforms at about 200 g.

In order to connect the first and second optical connector plugs 8 and 10, the locking leaf spring 9 of the second optical connector plug 2 is elastically deformed to form the guide pin hole 4a and the locking hole 9c. The guide pin 5 is inserted into the guide pin hole 4a in a state where they are substantially aligned with each other. Here, in the middle of insertion, the first
The coupling end faces of the ferrule 2 and the second ferrule 4 come into contact with each other, but the coupling end face of the first ferrule 2 is pressed by the coupling end face of the second ferrule 4 while compressing the coil spring 7, and the constriction of the guide pin 5 is reduced. Portion 5b is locking hole 9
The elastic deformation of the locking leaf spring 9 is released when the position coincides with the position c. As a result, the inner peripheral surface of the locking hole 9c has a constricted portion 5b.
And the guide pin 5 is prevented from coming off. Thus, the reaction force due to the compression of the coil spring 7 acts as a pressing force between the coupling end faces of the first and second ferrules 2 and 4. This force is preferably about 800 to 1000 g.

When the locking member to be locked to the constricted portion 5b of the guide pin 5 is the locking leaf spring 9 as in this embodiment,
The peripheral edge of the locking hole 9c of the locking leaf spring 9 is sandwiched between the rear end surface of the second ferrule 4 and the protrusion adjacent to the constricted portion 5b of the guide pin 5. The force acting on the stop leaf spring 9 is a shearing force with respect to the thickness direction of the locking portion 9b, which is a direction substantially orthogonal to the elastic deformation direction of the leaf spring portion 9a. Therefore, it is not necessary to select the wall thickness considering the strength of the locking leaf spring 9, and the thin locking leaf spring 9 can be selected regardless of the pressing force between the plugs, and the force required for spring deformation can be suppressed. This facilitates the workability in coupling the optical connectors and improves the coupling workability. The workability can be further improved by making the locking leaf spring 9 L-shaped so that it can be elastically deformed when gripping the plug, but the invention is not limited to this.

FIG. 2 shows an example of the shape of the locking hole of the locking leaf spring. In the example described above, a circular hole having a diameter slightly larger than that of the guide pin 5 is used. improves. In (B), the hatched circle indicates the constricted portion 5b. Further, as shown in (C), the contacting side of the locking hole with the guide pin is a straight locking hole 9e, and
Semi-circular constriction 5c instead of narrowing constriction
Then, the locked state between the guide pin 5 and the locking hole 9e can be stably maintained.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing an optical connector according to an embodiment of the present invention.

FIG. 2 is a schematic view showing another embodiment of the locking portion of the optical connector of the present invention.

FIG. 3 is a perspective view showing an example of an optical connector according to a conventional technique.

FIG. 4 is a cross-sectional view showing another example of the optical connector according to the related art.

FIG. 5 is a perspective view showing still another example of the optical connector according to the conventional technique.

[Explanation of symbols]

 1 1st optical fiber 2 1st ferrule 2a, 4a Guide pin hole 3 2nd optical fiber 4 2nd ferrule 5 Guide pin 5a, 5b, 5c Constriction part 6 Fixing member 7 Coil spring 8 1st optical connector Plug 9 Locking leaf spring member 9a Leaf spring portion 9b Locking portion 9c, 9d, 9e Locking hole 10 Second optical connector plug

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Makoto Sato 1-1-6 Uchisaiwaicho, Chiyoda-ku, Tokyo Nihon Telegraph and Telephone Corporation

Claims (3)

[Claims] 1. A pair of optical connector plugs respectively holding a first optical fiber and a second optical fiber,
An optical connector for optically coupling the first and second optical fibers with each other by positioning and connecting these optical connector members using two or more guide pins, wherein the first optical connector plug is the first A first ferrule that holds the optical fiber and has a plurality of guide pin holes through which the guide pins pass, and a fixing member that is at the rear end side of the first ferrule and holds one end of the guide pin, The guide pin is inserted between the first ferrule and the fixing member, and a guide pin that penetrates the guide pin hole of the first ferrule and has one end thereof held by the fixing member and has a constricted portion at the other end. The second optical connector plug is composed of a spring, and the second optical connector plug has a second ferrule that holds a second optical fiber and that has a plurality of guide pin holes through which the guide pins pass. And a locking member having a locking portion that engages with the constricted portion of the guide pin that penetrates the guide pin hole near the rear end surface of the second ferrule, and the guide pin is the second ferrule. In a state where it penetrates through the guide pin hole of and is engaged with the locking portion of the locking member,
The optical connector, wherein the spring biases the first ferrule with respect to the second ferrule. 2. The locking member according to claim 1, wherein the locking member is an L-shaped locking leaf spring whose base end is fixed to both side surfaces of the second ferrule, and the locking portion is the leaf spring. Is a locking hole formed at the tip of the guide pin and through which the guide pin can pass. When the locking plate spring is not elastically deformed, the peripheral edge of the locking hole is the guide pin hole of the second ferrule. An optical connector which closes a part of the opening and moves in a direction substantially orthogonal to the axial direction of the guide pin hole of the second ferrule by elastic deformation of the locking leaf spring. 3. The grip according to claim 2, wherein the locking leaf spring is elastically deformed by gripping both side surfaces of the second connector plug to open the locking hole and the guide pin hole of the second ferrule. Are substantially opposite to each other, and the other end portion of the guide pin is passed through the locking hole, and then the gripping state of the locking leaf spring is released, whereby the locking hole and the constricted portion of the guide pin are separated from each other. An optical connector characterized by being engaged.