JP6283006B2 - Optical connector parts - Google Patents

Description

  The present invention relates to an optical connector component.

  In order to prevent the eyes of the worker from being damaged by the optical signal emitted from the end of the optical transmission line (for example, optical fiber) or to prevent dust from adhering to the optical transmission line of the optical signal, It is known to provide a shutter within a housing that houses the end. For example, Patent Documents 1 and 2 describe an optical connector component having a shutter.

JP 2009-42353 A JP 2000-347075 A

  The shutter described in Patent Document 1 is urged to be opened and closed by a spring. However, in this case, since it is necessary to accommodate a spring, which is a member different from the shutter, in a narrow space in the housing, there arises a problem that the optical connector component is increased in size. On the other hand, as described in Patent Document 2, if the shutter is configured by bending an elastic metal, there is an advantage that it is not necessary to provide a spring as a separate member from the shutter.

  The shutter described in Patent Document 2 is provided with a first spring portion at a base portion that fixes the shutter, and the first spring portion is bent so that the base portion falls outward due to elastic deformation, so that the shutter portion is connected when the connector is connected. Evacuate. In order to bend the base portion so as to fall down in this way, it is necessary to provide a space (opening 1d and recess 1e in Patent Document 2) on the back surface of the base portion of the shutter. The area where the adapter 1) of literature 1 can be fixed becomes narrow. For this reason, in order to secure a region for fixing the base portion of the shutter, it is desirable that the shutter is deformed so that the shutter portion falls toward the base portion while the base portion of the shutter is fixed. However, if the space for retracting the shutter portion when the connector is connected is too small, stress may concentrate on a specific part (for example, the second spring portion 4d of Patent Document 2) due to the restriction, and the shutter may be plastically deformed. is there.

  An object of this invention is to suppress the plastic deformation of the deformation part of a shutter.

The main invention for achieving the above object is:
A first ferrule that holds an end portion of the first optical transmission line, an optical connector parts to be coupled to another optical connector part having a first housing for accommodating the first ferrule,
A second ferrule made of resin that holds the end of the second optical transmission line;
A second housing that houses the second ferrule;
A shield that shields an optical signal output from the second optical transmission line, and that contacts the first housing when the other optical connector component is inserted into the second housing; A shutter having a deforming portion that elastically deforms so as to retract the shielding portion from the optical path of the optical signal by contact with the first housing, and a base portion fixed to the second housing;
The second housing has a pair of fixing portions for fixing the base portion,
The pair of fixing portions are arranged with a wider interval than the width of the shielding portion,
The deforming portion is deformed so that a part of the shutter is disposed between the pair of fixing portions when the connector is connected,
The deforming portion includes a first deforming portion and a second deforming portion disposed on the shielding portion side with respect to the first deforming portion,
When the connector is connected, the first deformation portion and the second deformation portion are deformed,
The first deformable portion and the second deformable portion are optical connector parts that are arranged at positions that do not block the front of the first housing.

  Other characteristics of the present invention will be made clear by the description and drawings described later.

  According to the present invention, plastic deformation of the deformed portion of the shutter can be suppressed.

FIG. 1 is a perspective view of the optical connector component 1 and the plug-side optical connector 100 of the first embodiment. 2A and 2B are sectional views of the optical connector component 1, FIG. 2A is a sectional view before connector connection, and FIG. 2B is a sectional view when the connector is connected. FIG. 3 is an exploded view showing the configuration of the optical connector component 1. 4A and 4B are explanatory diagrams for assembling the optical connector component 1. FIG. FIG. 5A is an explanatory diagram of the shape of the shutter 30 according to the first embodiment. FIG. 5B is an explanatory diagram of the shape of the shutter 30 according to the first modification. FIG. 5C is an explanatory diagram of the shape of the shutter 30 according to the second modification. FIG. 6A is an explanatory diagram of the cleaning tool 2 for cleaning the end face of the ferrule. FIG. 6B is an explanatory diagram of the shape of the shutter 30 according to the third modified example. FIG. 7 is an explanatory view showing an optical connector component 1 ′ according to the second embodiment. FIG. 8 is an explanatory diagram of attachment of the shutter 30 and the absorption plate 40 to the optical connector component 1 ′ of the second embodiment.

  At least the following matters will be apparent from the description and drawings described below.

A housing that houses the end of the optical transmission path;
A shielding part that shields an optical signal output from the optical transmission line; and a deformation part that elastically deforms so as to retract the shielding part from the optical path of the optical signal when a connector is connected to the optical transmission line. A base portion fixed to the housing, and a shutter having
The housing has a pair of fixing portions for fixing the base portion,
The pair of fixing portions are arranged with a wider interval than the width of the shielding portion,
The optical connector component is characterized in that the deforming portion is deformed so that a part of the shutter is disposed between the pair of fixing portions when the connector is connected. According to such an optical connector component, even when the deformation amount of the deformation portion is small when the connector is connected, the shielding portion can be retracted from the optical path of the optical signal, so that plastic deformation of the deformation portion of the shutter can be suppressed.

  The deforming portion includes a first deforming portion and a second deforming portion disposed closer to the shielding portion than the first deforming portion, and the first deforming portion and the second deforming portion when the connector is connected. It is desirable that the part deforms. Thereby, since stress can be disperse | distributed, the plastic deformation of the deformation | transformation part of a shutter can be suppressed.

  It has higher heat resistance than the housing and includes a light absorbing member that is irradiated with the optical signal reflected by the shielding portion, and the fixing portion fixes the light absorbing member that houses the base portion, It is desirable to fix the base part. Thereby, it can suppress that a housing melt | dissolves with reflected light.

  It is desirable that the light absorbing member can be attached to and detached from the housing. Thereby, even if the light absorbing member is deteriorated by the reflected light, the deteriorated light absorbing member can be replaced.

  The shielding portion has a proximal end region on the deformation portion side and an end region, and a bent portion that is convex when viewed from the connector insertion port is between the proximal end region and the end region. It is desirable that it be formed. Thereby, it can suppress that the cleaning tool inserted from the connector insertion port becomes difficult to come off.

  The housing may be a receptacle in which the receptacle-side optical connector is accommodated on one side and the plug-side optical connector is detachable on the other side. Alternatively, the housing may be an adapter in which an optical connector can be attached and detached from both sides.

=== First Embodiment ===
<Basic configuration of optical connector parts>
FIG. 1 is a perspective view of the optical connector component 1 and the plug-side optical connector 100 of the first embodiment. 2A and 2B are sectional views of the optical connector component 1, FIG. 2A is a sectional view before connector connection, and FIG. 2B is a sectional view when the connector is connected. FIG. 3 is an exploded view showing the configuration of the optical connector component 1. 4A and 4B are explanatory diagrams for assembling the optical connector component 1. FIG.

  In the following description, each direction is defined as shown in the figure. That is, the direction in which the plug-side optical connector 100 is attached to and detached from the optical connector component 1 is “front-rear direction”, the side facing the plug-side optical connector 100 in the optical connector component 1 is “front”, and the opposite side is “rear” . Further, the width direction of the plug-side optical connector 100 (the direction in which a plurality of optical fibers are arranged) is defined as the “left-right direction”. A direction perpendicular to the front-rear direction and the left-right direction is referred to as “vertical direction”.

  The optical connector component 1 of the first embodiment is a receptacle with an optical connector to which the plug-side optical connector 100 can be attached and detached. The optical connector component 1 of the first embodiment includes a housing (receptacle) 10, a metal clip 18, a receptacle-side optical connector 20, a shutter 30, and an absorption plate 40 (corresponding to a light absorption member).

The housing 10 is a cylindrical member and is a member that accommodates an end portion of an optical connector serving as an optical transmission path. A housing part (rear housing part, receptacle side housing part) for housing a receptacle-side optical connector 20 (described later) is provided on the rear side of the housing 10, and a plug-side optical connector 100 (MPO connector) is disposed on the front side. The housing part (front side accommodating part, plug side accommodating part) which accommodates detachably is provided. In the housing portion of the plug-side optical connector 100, the shutter 30 and the absorption plate 40 are housed.
An engagement hole 12 is provided in the housing 10. The engagement hole 12 is a portion (hole) that engages with the latch portion 46 of the absorption plate 40, and is provided on the upper surface of the housing 10.

  The housing 10 has a fixing portion 14 on each of the left and right sides. The pair of fixing portions 14 are portions for fixing the base portion 34 of the shutter 30. In the first embodiment, the fixing portion 14 fixes the base portion 34 of the shutter 30 by fixing the left and right edges of the absorption plate 40. As shown in FIG. 4B, the fixing portion 14 is formed to protrude inward from the inner walls of the left and right sides of the housing 10, and the pair of fixing portions 14 has a width L2 (left and right) of the shutter shielding portion 32 and the deformation portion 33. They are arranged on the left and right sides with an interval L1 wider than the dimension L2). Thereby, a part of the shutter 30 at the time of deformation can be disposed between the pair of fixing portions 14. There is a gap between the fixed portion 14 and the upper wall of the housing 10, and a rail-shaped groove (rail portion 14A) is formed.

  The metal clip 18 is a member for attaching the housing 10 to a substrate (not shown). Further, the metal clip 18 is disposed on the engagement hole 12 of the housing 10 and has a function of covering (hiding) the blue absorption plate 40 (latch portion 46).

  The receptacle-side optical connector 20 includes a ferrule 22, a guide pin 23, a boot 24, and a floating mechanism 25.

  The ferrule 22 is a member that holds an end portion of an optical fiber that becomes an optical transmission line, and is integrally formed of resin. The front end face of the ferrule 22 serves as a connection end face to be connected to the counterpart optical connector (here, the plug-side optical connector 100). The ferrule 22 includes a main body portion 22A and a flange portion 22B. The main body 22A is provided with two guide holes 22C and a plurality of optical fiber holes 22D. The ends of the plurality of optical fibers are held inside the main body 22A.

  The flange portion 22 </ b> B protrudes outward from the outer peripheral surface of the main body portion 22 </ b> A and contacts (contacts) a protrusion formed on the inner wall of the housing 10.

  The guide hole 22 </ b> C is a hole for inserting the guide pin 23. The guide hole 22 </ b> C penetrates the main body portion 22 </ b> A in the front-rear direction, and two guide holes 22 </ b> C are opened on the front end face of the ferrule 22. The two guide holes 22C are formed at intervals in the left-right direction so as to sandwich the plurality of optical fiber holes 22D from the left and right.

  The optical fiber hole 22D is a hole for inserting and positioning an optical fiber. A bare fiber having a coating removed from the optical fiber core wire is inserted into the optical fiber hole 22D. A plurality of optical fiber holes 22D are arranged in the left-right direction, and each optical fiber hole 22D is parallel to the front-rear direction. That is, a plurality of optical fiber holes 22D parallel to each other are arranged in the left-right direction. Further, the end face of the optical fiber is exposed from each optical fiber hole 22D on the front end face of the ferrule 22.

  The guide pin 23 positions the ferrule 22 and the ferrule on the other side (here, the plug-side optical connector 100). The guide pin 23 is inserted into the guide hole 22C of the ferrule 22 and penetrates the main body portion 22A of the ferrule 22 in the front-rear direction. Further, as shown in FIG. 2A, the tip end (front end) of the guide pin 23 protrudes from the front end face of the ferrule 22.

  The boot 24 is a member for relaxing the bending of the optical fiber. The boot 24 is preferably made of a flexible material such as rubber or elastomer, but may be made of a low flexibility material such as resin or metal. The boot 24 reduces light transmission loss or protects the optical fiber itself.

  The floating mechanism 25 is a mechanism for pressing the ferrule 22 to the front side so as to be retractable. The floating mechanism 25 includes a pin clamp 26, a spring 27, and a spring push 28.

  The pink lamp 26 clamps and holds the guide pin 23. The flange of the guide pin 23 is disposed between the rear end surface of the ferrule 22 and the front end surface of the pin clamp 26, and the guide pin 23 is prevented from coming off in the front-rear direction.

  The spring 27 urges the ferrule 22 to force forward via the pin clamp 26 by the repulsive force of the spring 27. On the rear side of the ferrule 22, a flange portion 22 </ b> B with an outer periphery protruding is formed, and a front end surface of the flange portion 22 </ b> B comes into contact with a protrusion 15 (see FIG. 2A) formed on the inner surface of the housing 10. Further movement of the ferrule 22 to the front side is restricted (the front drop of the ferrule 22 is restricted).

  The spring push 28 is a member for accommodating the spring 27 in a state in which the spring 27 is elastically deformed (compressed). Thus, the ferrule 22 is accommodated in the housing 10 so as to be movable rearward while being urged forward by the repulsive force of the spring 27. By accommodating the ferrule 22 in this way, when the plug-side optical connector 100 is connected, it is possible to maintain a state in which the end surfaces of the ferrule are physically abutted with a predetermined force.

  The spring push 28 includes a frame-shaped main body 28A and a pair of fitting protruding wall portions 28B. A fiber insertion hole for inserting an optical fiber is formed in the frame-shaped main body 28A. The pair of fitting protruding wall portions 28B are portions that are formed to protrude from the left and right sides of the frame-shaped main body 28A toward the front side. The pair of fitting projection walls 28B are formed with locking claws 28C protruding outward, and the locking claws 28C are fitted into locking holes (not shown) formed on the inner surface of the housing 10. The spring push 28 is fixed to the housing 10. At this time, the spring 27 is accommodated in a state of being compressed and deformed between the pin clamp 26 and the spring push 28. However, when the locking claw 28C is fitted into the locking hole of the housing 10, the spring push 28 is moved into the housing. 10 is prevented from coming out from the rear side.

  The shutter 30 is a member that shields an optical signal emitted from the optical fiber of the receptacle-side optical connector 20 in order to suppress damage to eyes caused by light when the plug-side optical connector 100 is not accommodated in the housing 10. Yes (eye safety). Further, the shutter 30 has a function of opening and closing according to the attachment / detachment of the plug-side optical connector 100. Furthermore, the shutter 30 also has a function of protecting the receptacle-side optical connector 20 from dust when the plug-side optical connector 100 is not provided (when not accommodated in the housing 10).

  The shutter 30 is made of metal and includes a shielding part 32, a deforming part 33, and a base part 34. The shutter 30 is configured by bending a metal plate. The shutter 30 is a V-shaped member that is bent at the deformable portion 32.

  The shielding part 32 is a part that shields an optical signal emitted from the optical fiber of the receptacle-side optical connector 20. In the present embodiment, the shielding unit 32 shields the optical signal and reflects the optical signal toward the lower surface (absorbing surface 42) of the absorbing plate 40. However, the shielding unit 32 may absorb the optical signal without reflecting the optical signal. The rear surface of the shield 32 is a reflective surface that reflects the optical signal. The front surface of the shielding portion 32 is a contact surface that comes into contact with the plug-side optical connector 100 when the plug-side optical connector 100 is inserted into the housing 10. The shielding portion 32 has a width L2 (dimension L2 in the left-right direction) that can shield a plurality of optical signals of the receptacle-side optical connector 20.

  The deforming part 33 connects the shielding part 32 and the base part 34, and allows the shielding part 32 to be opened and closed by being deformed (elastically deformed). The deformation portion 33 is deformed when the plug-side connector 100 is connected and when the plug-side connector 100 is removed. Specifically, the deforming portion 33 is deformed so that the shielding portion 32 is opened (toward upward) when the plug-side connector 100 is connected. In other words, the deforming portion 33 is deformed so as to retract the shielding portion 32 from the optical path of the optical signal when the plug-side connector 100 is connected. Moreover, the deformation | transformation part 33 deform | transforms so that the shielding part 32 may be closed at the time of extraction of the plug side connector 100 (it goes below). In other words, the deforming portion 33 is deformed so that the shielding portion 32 shields the optical path of the optical signal when the plug-side connector 100 is removed.

  The base part 34 fixes the shielding part 32 to the absorption plate 40. As shown in FIG. 3, the base part 34 has an engagement hole 34A and an edge part 34B.

  The engagement hole 34 </ b> A is a portion that engages with the locking portion 44 </ b> A of the absorption plate 40. The shutter 30 (shielding portion 32) is fixed to the absorbing plate 40 by engaging the engaging hole 34A with the locking portion 44A.

  The edge part 34B is a part of the edge of the base part 34 in the left-right direction, and is a part gripped by the grip part 44B of the absorption plate 40.

  The absorption plate 40 is irradiated with the reflected light reflected by the shielding portion 32 of the shutter 30 and absorbs the reflected light. By absorbing the reflected light in this manner, the housing 10 can be prevented from being melted by the reflected light. The absorption plate 40 also has a function of fixing the base portion 34 of the shutter 30.

  The absorption plate 40 is formed of a heat resistant resin (polyetherimide resin, for example, Ultem 1000R manufactured by SABIC), and has higher heat resistance than the housing 10. In this embodiment, the housing 10 is melted by irradiation of the reflected light by providing the absorption plate 40 (absorbing surface 42) that has higher heat resistance than the housing 10 and is irradiated with the reflected light reflected by the shielding portion 32. Can be suppressed.

  Moreover, the color of the absorption plate 40 of this embodiment is blue. This is because the reflected light is appropriately absorbed. If it is black, the reflected light is absorbed too much, and the absorption plate 40 may melt. In addition, in order to hide the conspicuous blue color, the absorption plate 40 (latch portion 46) is hidden by the metal clip 18.

  The absorption plate 40 includes an absorption surface 42, a storage portion 44, and a latch portion 46.

  The absorption surface 42 is a lower surface of the absorption plate 40 and is a surface to which reflected light (optical signal) from the shielding portion 32 of the shutter 30 is irradiated.

  The accommodating portion 44 is provided on the upper surface of the absorption plate 40 and has a function of accommodating and fixing the base portion 34 of the shutter 30. In this embodiment, since the accommodating part 44 is provided on the upper surface of the absorption plate 40, the absorption plate 40 can be arrange | positioned so that the base part 34 of the shutter 30 may be covered. Accordingly, even if the plug-side optical connector 100 is repeatedly attached and detached, the deforming portion 33 is gradually deformed, and even if the irradiation position of the reflected light gradually approaches the root of the shielding portion 32 of the shutter 30, the absorbing plate 40 is Since the base part 34 of 30 is covered, the absorption plate 40 (absorption surface 42) continues absorbing the reflected light. In addition, since the absorption plate 40 covers the base portion 34 of the shutter 30, the length of the base portion 34 of the shutter 30 can be increased and the shutter 30 can be easily fixed.

  The accommodating portion 44 has a locking portion 44A, a gripping portion 44B, and an edge portion 44C.

  The locking portion 44 </ b> A is a portion that engages with the engagement hole 34 </ b> A of the shutter 30. The locking portion 44 </ b> A also has a function of fixing the base portion 34 of the shutter 30 to the housing portion 44 of the absorption plate 40. 44 A of latching | locking parts are provided in the accommodating part 44 so that it may protrude on the upper side (wall surface side of the housing 10).

  The grip portion 44B is a portion that grips the edge portion 34B of the shutter 30 from above and below, and has a shape (concave shape) that fits with the edge portion 34B. A pair of gripping portions 44 </ b> B are provided on both sides in the left-right direction of the accommodating portion 44 corresponding to the edge portions 34 </ b> B at both ends in the left-right direction of the shutter 30. Further, the grip portion 44B is provided along the front-rear direction, and the base portion 34 (edge portion 34B) of the shutter 30 is slidable in the front-rear direction while being gripped by the grip portion 44B. Since there is a thickness of the upper portion of the grip portion 44B (a portion above the edge portion 34B of the shutter 30), the base portion 34 of the shutter 30 is not in contact with the inner wall surface of the housing 10. As a result, when the absorption surface 42 of the absorption plate 40 becomes hot, heat is easily radiated by the shutter 30 while suppressing heat transfer to the housing 10.

  The edge part 44C is an edge part in the left-right direction of the absorption surface 42 of the absorption plate 40, and is a part that slides on the fixing part 14 (rail part 14A) of the housing 10 (see FIG. 4B).

  The latch portion 46 is a portion that is caught in the engagement hole 12 of the housing 10. Further, the latch portion 46 engages the engagement hole 12 to fix the absorption plate 40 to the housing 10. The latch portion 46 is provided so as to protrude upward (convexly upward) at the rear end portion of the absorption plate 40.

  The fixing portion 14 of the housing 10 is provided in the accommodating portion of the plug-side optical connector 100 (see FIGS. 2A and 4B). The fixing portion 14 is configured to grip the left and right edge portions 44C of the absorption plate 40 from the vertical direction so as to be movable in the front-rear direction. Further, the absorption plate 40 can be attached to the rail portion 14 </ b> A on the fixed portion 14 in a state where the base portion 34 of the shutter 30 is accommodated in the accommodation portion 44 of the absorption plate 40. By providing the fixing portion 14 in this way, the absorption plate 40 can be attached to and detached from the housing 10. Thereby, even if the absorption plate 40 is deteriorated by the reflected light, the deteriorated absorption plate 40 can be replaced.

  The fixing portion 14 is disposed on the opposite side (upper side) of the key groove of the housing 10. This is because the thickness of the housing 10 is thin on the keyway side.

<Assembly method of optical connector part 1>
Hereinafter, a method for assembling the optical connector component 1 (a method for attaching the shutter 30 and the absorbing plate 40 to the housing 10) will be described.

  First, the shutter 30 is fixed to the absorption plate 40. That is, the edge portion 34B of the shutter 30 is slid to the grip portion 44B of the absorption plate 40. When sliding, the engaging hole 34A of the shutter 30 and the engaging portion 44A of the absorbing plate 40 engage as shown in FIG. 4A. Thereby, the base part 34 of the shutter 30 is fixed to the accommodating part 44 of the absorption plate 40. In other words, the shutter 30 (the shielding portion 32) is fixed to the absorption plate 40.

  Next, the absorption plate 40 to which the shutter 30 is fixed is fixed in the housing 10. Here, the edge portion 44C of the absorption plate 40 is slid onto the rail portion 14A on the fixed portion 14 of the housing 10 (see FIGS. 4A and 4B). When sliding, the latch portion 46 of the absorption plate 40 is caught in the engagement hole 12 of the housing 10 (see FIG. 2A). Thereby, the absorption plate 40 is fixed to the fixing portion 14 of the housing 10. Further, since the shutter 30 is fixed to the absorption plate 40, the shutter 30 is fixed to the housing 10.

  Thus, in this embodiment, since the absorption plate 40 to which the shutter 30 is fixed is attached in the housing 10 in advance, the attachment work in the narrow housing 10 is only required once.

<Operation of optical connector part 1>
When the plug-side optical connector 100 is inserted (accommodated) into the housing 10 of the optical connector component 1, the housing of the plug-side optical connector 100 contacts the shutter 30. Thereby, the deformation | transformation part 33 of the shutter 30 deform | transforms and the shielding part 32 opens (it goes upwards). Then, the end faces of the plug-side optical connector 100 and the receptacle-side optical connector 20 (end faces of the optical fibers) are connected (optically connected).

  When the plug-side optical connector 100 is removed from the housing 10, the shielding portion 32 of the shutter 30 closes (goes downward) in an attempt to return the deformable portion 33. For this reason, the optical signal emitted from the optical fiber of the receptacle-side optical connector 20 is reflected by the shielding part 32 and is irradiated on the absorption surface 42 of the absorption plate 40. Therefore, the optical signal can be shielded and the damage to the eyes caused by the optical signal can be suppressed (eye safety). Moreover, since the absorption plate 40 absorbs reflected light and has higher heat resistance than the housing 10, it can suppress that the housing 10 melt | dissolves by irradiation of reflected light.

<Regarding Deformer 33 of Shutter 30>
FIG. 5A is an explanatory diagram of the shape of the shutter 30 according to the first embodiment. The deformation portion 33 of the shutter 30 of the present embodiment includes a base side bending portion 33A, a shielding side bending portion 33B, and an intermediate bending portion 33C.

The base-side bent portion 33A is a portion bent with respect to the base portion 34, and is a portion (first deformable portion) that is elastically deformed when the shutter 30 is opened and closed. The metal plate is bent perpendicularly in the front-rear direction from the base part 34 perpendicular to the up-down direction by the base-side bent part 33A. The base-side bent portion 33A is a mountain-folded portion that is convex when viewed from the front side (insertion side of the plug-side connector 100), and is deformed so that the mountain-folded fold is narrowed when the connector is connected. In the present embodiment, the pair of fixing portions 14 of the housing 10 (the portion that fixes the shutter 30 via the absorption plate 40 and the portion that protrudes inward from the left and right inner walls of the housing) are the shielding portions 32 of the shutter 30. (And the deformation | transformation part 33) are arrange | positioned with the space | interval L1 wider than the width | variety L2 (refer FIG. 4B). Therefore, the base side bent portion 33A can be deformed without being obstructed by the fixing portion 14 (see also FIG. 2B).
Since the front edge of the absorbing plate 40 is located on the back side of the base side bent portion 33A, the base side bent portion 33A is easily deformed with the front edge of the absorbing plate 40 (the front edge of the base portion 34) as a base point. Yes. Further, since the inclined surface 40A is formed at the front edge of the absorption plate 40, the base with the front edge of the absorption plate 40 as a base point is not hindered by the thickness of the absorption plate 40 that fixes the base portion 34. The side bent portion 33A can be deformed.

  The shielding-side bent portion 33B is a bent portion disposed on the shielding portion 32 side with respect to the base-side bent portion 33A, and is a portion (second deforming portion) that is elastically deformed when the shutter 30 is opened and closed. The metal plate is bent by the shielding side bending portion 33B so that the shielding portion 32 can be in a position where the optical path of the optical signal can be shielded. The shielding-side bent portion 33B is a valley-folded portion that is concave when viewed from the front side, and is deformed so that a valley-folded fold is widened when the connector is connected.

  The intermediate bent portion 33C is a portion bent between the base side bent portion 33A and the shield side bent portion 33B. The intermediate bending portion 33C may not be elastically deformed when the shutter 30 is opened and closed. Further, the intermediate bending portion 33C may be omitted.

  In the present embodiment, since the pair of fixing portions 14 of the housing 10 are arranged with an interval L1 wider than the shielding portion 32 of the shutter 30 and the width L2 of the deformation portion 33 (see FIG. 4B), the shutter is connected when the connector is connected. The deformation part 33 can be deformed so that a part of 30 (a part of the shielding part 32 and a part of the deformation part 33) is disposed between the pair of fixing parts 14 (see also FIG. 2B). For this reason, even if the deformation amount of the deformation portion 33 is small when the connector is connected, the shielding portion 32 can be retracted from the optical path of the optical signal, so that the deformation portion 33 can be prevented from being plastically deformed. If the interval L1 (see FIG. 4B) between the pair of fixing portions 14 is narrower than the shielding portion 32 of the shutter 30 and the width L2 of the deformation portion 33, the shielding portion 32 is retracted between the pair of fixing portions 14. Therefore, when the shielding portion 32 is retracted in the narrow gap between the fixing portion 14 and the plug-side optical connector 100, the deformation portion 33 (for example, the shielding-side bent portion 33B) needs to be largely deformed, and the deformation portion 33 may be plastically deformed.

  In addition, in this embodiment, since the plastic deformation of the deformable portion 33 can be suppressed, the shield portion 32 can be designed to be short (if the deformable portion 33 is plastically deformed, the shield portion 32 is taken into account when the plastic deformable portion is taken into account. Need to be long). For this reason, in the present embodiment, when the connector is connected, it is only necessary to retract the relatively short shielding portion 32, so that the deformation amount of the deformation portion 33 can be further reduced. That is, since the shielding part 32 can be designed to be short by suppressing plastic deformation of the deforming part 33, a synergistic effect can be obtained in which plastic deformation of the deforming part 33 can be further suppressed.

Moreover, in this embodiment, the deformation | transformation part 33 is the shielding side bending part 33B (2nd deformation | transformation) arrange | positioned at the side of the shielding part 32 rather than the base side bending part 33A (1st deformation part) 33A. The base side bent portion 33A and the shield side bent portion 33B are deformed when the connector is connected. Thereby, since it can suppress that stress concentrates on a specific site | part (for example, the shielding side bending part 33B which is a 2nd deformation | transformation part), the plastic deformation of the deformation | transformation part 33 can be suppressed.
In the present embodiment, when the base side bent portion 33A (first deformed portion) is deformed when the connector is connected, the shield side bent portion 33B (second deformed portion) is positioned between the pair of fixed portions. It is deformed by. Thereby, the deformation amount of the shielding side bending part 33B can be reduced, and the plastic deformation of the shielding side bending part 33B can be suppressed.

  Moreover, in this embodiment, the fixing | fixed part 14 is fixing the base part 34 by fixing the absorption plate 40 (light absorption member) which accommodated the base part 34 of the shutter 30. FIG. Since the absorption plate 40 absorbs reflected light and has higher heat resistance than the housing 10, it is possible to suppress the housing 10 from being melted by irradiation of the reflected light. However, the fixing portion 14 may directly fix the base portion 34 of the shutter 30 without providing the absorption plate 40. When the fixing portion 14 directly fixes the base portion 34 of the shutter 30, in order to suppress the deformation of the base side bending portion 33A from being hindered by the thickness of the fixing portion 14 that fixes the base portion 34. It is desirable that an inclined surface (an inclined surface corresponding to the inclined surface 40 </ b> A of the absorption plate 40) is formed on the front edge of the fixed portion 14.

<First and second modified examples>
FIG. 5B is an explanatory diagram of the shape of the shutter 30 according to the first modification. The deformation part 33 of the shutter 30 of the first modification has a base side bending part 33A and a shielding side bending part 33B, but does not have an intermediate bending part 33C. Further, the shielding-side bent portion 33B is a mountain-folded portion that is convex when viewed from the front side, and is deformed so that the mountain-folded fold is narrowed when the connector is connected.

  FIG. 5C is an explanatory diagram of the shape of the shutter 30 according to the second modification. The deformation part 33 of the shutter 30 of the second modification has a base side bending part 33A (first deformation part) and a shielding side bending part 33B (second deformation part), but does not have an intermediate bending part 33C. In the second modified example, the base-side bent portion 33A is formed as a portion that is curved so as to be convex when viewed from the front side.

  Also in the first and second modified examples, if the pair of fixing portions 14 of the housing 10 are arranged with a gap wider than the width of the shielding portion 32 and the deforming portion 33 of the shutter 30, the connector Since the deformable portion 33 can be deformed so that part of the shutter 30 (part of the shielding portion 32 or part of the deformable portion 33) is disposed between the pair of fixing portions 14 at the time of connection, Plastic deformation can be suppressed. Also in the first and second modified examples, if both the base-side bent portion 33A and the shield-side bent portion 33B are deformed when the connector is connected, a specific part (for example, the shield that is the second deformed portion) is formed. Since the stress can be suppressed from concentrating on the side bent portion 33B), the plastic deformation of the deformable portion 33 can be suppressed. If the deformed portion is formed by bending as in the base side bent portion 33A of the second modified example, the stress can be further dispersed, which is particularly advantageous for suppressing plastic deformation of the deformed portion 33. .

<Third Modification>
FIG. 6A is an explanatory diagram of the cleaning tool 2 for cleaning the end face of the ferrule. The cleaning tool 2 is a tool for cleaning a surface to be cleaned (for example, an end surface of the ferrule 22). The cleaning tool 2 includes a tool main body 3 and an insertion portion 4 extending from the tool main body. A head member 5 is provided in the insertion portion 4, and a belt-like cleaning body 6 is wound around the pressing surface (end surface) of the head member 5. The cleaning body 6 (and the end of the head member 5) is exposed to the outside from the distal end portion of the insertion portion 4 so that the cleaning body 6 can be pressed against the surface to be cleaned. At the time of the cleaning operation, the operator holds the tool body 3 and moves the tool body 3 toward the insertion portion 4 while pressing the cleaning body 6 wound around the pressing surface of the head member 5 against the surface to be cleaned ( (Pushing operation), then, the gripping tool body 3 is moved backward with respect to the insertion portion 4 (pulling operation), and the head member 5 is separated from the surface to be cleaned. By utilizing the relative movement between the tool main body 3 and the insertion portion 4 at this time, the unused cleaning body 6 is supplied and the used cleaning body 6 is collected.

  By the way, when the insertion portion 4 of the cleaning tool 2 is inserted from the insertion port (connector insertion port) of the plug-side optical connector 100 in order to clean the end face of the ferrule 22 of the optical connector component 1 of the above-described embodiment, the shutter 30 The end of the shielding part 32 may be stuck in the head member 5 or the cleaning body 6 exposed from the insertion part 4, and the insertion part 4 may not be removed after cleaning.

  FIG. 6B is an explanatory diagram of the shape of the shutter 30 according to the third modified example. The shielding part 32 of the shutter 30 of the third modified example is composed of a base end area 32A and an end area 32B. The proximal end region 32 </ b> A is a region on the deformation portion 33 side, and the end portion region 32 </ b> B is an end portion region of the shielding portion 32. A bent portion is formed between the base end region 32A and the end region 32B. The bent portion is a fold-like fold that is convex when viewed from the front side (connector insertion opening side). In other words, when viewed from the side of the cleaning tool 2 inserted into the optical connector component 1, the bent portion between the base end region 32A and the end region 32B is formed to be convex. According to the third modification, the inclination of the end portion region 32B of the shielding portion 32 with respect to the front-rear direction (the insertion / extraction direction of the insertion portion 4 of the cleaning tool 2) is smaller than that of the proximal end region 32A. The end portion of the portion 32 (the end portion of the end region 32 </ b> B) is less likely to pierce the head member 5 and the cleaning body 6 exposed from the insertion portion 4. For this reason, it becomes difficult to produce the situation where the cleaning tool 2 inserted from the insertion port becomes difficult to come off.

=== Second Embodiment ===
The optical connector component of the second embodiment is different from the first embodiment in that it is an adapter.

  FIG. 7 is an explanatory view showing an optical connector component 1 ′ according to the second embodiment. Moreover, FIG. 8 is explanatory drawing of attachment of the shutter 30 and the absorption plate 40 to optical connector component 1 'of 2nd Embodiment. The optical connector component 1 ′ of the second embodiment is an optical connector adapter that can be attached and detached from both sides.

  The housing (adapter) 10 ′ of the optical connector component 1 ′ of the second embodiment is provided with a housing portion that detachably houses the optical connector 100 ′ (MPO connector) on both sides in the front-rear direction. The optical connector 100 ′ is the same as the plug-side optical connector 100 of the first embodiment. Further, in the optical connector component 1 ′ of the second embodiment, the structure of the housing portion of the housing 10 ′ is upside down on the front side and the rear side in order to reduce the size. That is, as shown in FIG. 7, one optical connector 100 ′ and the other optical connector 100 ′ are accommodated in the housing 10 ′ upside down.

  Moreover, as shown in FIG. 8, the shutter 30 and the absorption plate 40 are accommodated in the respective accommodating portions on the front side and the rear side of the housing 10 ′. Here, the absorption plate 40 to which the shutter 30 is fixed is attached to each housing portion of the housing 10 '(upside down). However, it is not restricted to this, You may accommodate the shutter 30 and the absorption plate 40 only in one side. In this case, when the optical connector 100 ′ is accommodated in one side of the housing 10 ′, the optical connector 100 ′ may be accommodated in the accommodating portion on the side where the optical signal is shielded / reflected by the shutter 30.

  Also in the second embodiment, as in the first embodiment, a pair of fixing portions (not shown) of the housing 10 ′ are arranged with a gap wider than the width of the shielding portion 32 and the deformation portion 33 of the shutter 30. If so, the deformable portion 33 can be deformed so that a part of the shutter 30 ′ is disposed between the pair of fixed portions when the connector is connected, so that plastic deformation of the deformable portion 33 can be suppressed.

=== Others ===
The above-described embodiments are for facilitating the understanding of the present invention, and are not intended to limit the present invention. The present invention can be modified and improved without departing from the gist thereof, and it goes without saying that the present invention includes equivalents thereof.

1 optical connector parts, 1 'optical connector parts,
3 Cleaning tool, 4 Tip side housing,
5 Head member, 6 Cleaning body,
10 housing (receptacle), 10 'housing (adapter),
12 engaging hole, 14 fixing part, 14A rail part, 18 metal clip,
20 Receptacle side optical connector, 22 Ferrule,
22A body part, 22B collar part, 22C guide hole, 22D optical fiber hole,
23 guide pins, 24 boots, 25 floating mechanism,
26 Pink lamp, 27 Spring, 28 Spring push,
28A frame-shaped main body, 28B protruding wall for fitting, 28C locking claw,
30 shutter, 32 shielding part, 33 deformation part,
33A Base side bent part (first deformed part), 33B Shield side bent part (second deformed part),
33C intermediate bending part, 34 base part,
34A engagement hole, 34B edge,
40 absorbing plate, 40A inclined surface, 42 absorbing surface,
44 accommodating portion, 44A locking portion, 44B gripping portion, 44C edge,
46 Latch part,
100 plug side optical connector, 100 'optical connector

Claims (6)

A first ferrule that holds an end portion of the first optical transmission line, an optical connector parts to be coupled to another optical connector part having a first housing for accommodating the first ferrule,
A second ferrule made of resin that holds the end of the second optical transmission line;
A second housing that houses the second ferrule;
A shield that shields an optical signal output from the second optical transmission line, and that contacts the first housing when the other optical connector component is inserted into the second housing; A shutter having a deforming portion that elastically deforms so as to retract the shielding portion from the optical path of the optical signal by contact with the first housing, and a base portion fixed to the second housing;
The second housing has a pair of fixing portions for fixing the base portion,
The pair of fixing portions are arranged with a wider interval than the width of the shielding portion,
The deforming portion is deformed so that a part of the shutter is disposed between the pair of fixing portions when the connector is connected,
The deforming portion includes a first deforming portion and a second deforming portion disposed on the shielding portion side with respect to the first deforming portion,
When the connector is connected, the first deformation portion and the second deformation portion are deformed,
The optical connector component, wherein the first deformable portion and the second deformable portion are arranged at positions that do not block the front of the first housing. The optical connector component according to claim 1,
A heat absorbing member that has higher heat resistance than the second housing and is irradiated with the optical signal reflected by the shielding portion;
The optical connector component, wherein the fixing portion fixes the base portion by fixing the light absorbing member that houses the base portion. The optical connector component according to claim 2,
The optical connector component, wherein the second housing is detachably attachable to the light absorbing member. The optical connector part according to claim 1,
The shielding portion has a proximal end region on the deformation portion side and an end region,
An optical connector component, wherein a bent portion that is convex when viewed from a connector insertion port is formed between the base end region and the end region. An optical connector component according to any one of claims 1 to 4,
The optical connector component, wherein the second housing is a receptacle in which a receptacle-side optical connector is accommodated on one side and a plug-side optical connector is detachable on the other side. An optical connector component according to any one of claims 1 to 4,
The optical connector component, wherein the second housing is an adapter to which an optical connector can be attached and detached from both sides.

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