JP4848793B2 - Pluggable optical transceiver - Google Patents

Description

  The present invention relates to an insertion / removal mechanism between an optical transceiver and a cage of a host device to which the optical transceiver is inserted and removed.

  The pluggable optical transceiver is used by being inserted into a cage of a host device (host system). The cage is a metal box-shaped part that is open at one end, and has an electrical connector at the far end that is mounted on the host device and connected to the board of the host device. The open end opens in the face panel of the host device. Is done. The pluggable optical transceiver is used by being inserted into the cage mounted on the host device in this way, and the plug mounted at the rear end is inserted into the electrical connector in the cage. In particular, a pluggable optical transceiver having a configuration in which a plug can be inserted / removed without disconnecting the power supply of the host device is called a hot-pluggable optical transceiver.

  The pluggable optical transceiver must be provided with an insertion / removal mechanism for insertion / removal into / from the host device cage. In particular, when the end of the optical transmission cable (optical connector) is inserted into the optical receptacle of the optical transceiver, it is prohibited to remove the optical transceiver from the cage, and the end of the optical transmission cable is inserted into the optical receptacle. There is a need for an insertion / removal mechanism that can disengage the optical transceiver from the cage only when not. Various proposals have been made for the insertion / removal mechanism between the optical transceiver and the cage.

  FIG. 8 is a diagram showing an optical transceiver having a cage insertion / removal mechanism described in Patent Document 1, and an optical transceiver 500 is a combination of a wire frame-shaped bail 510 and a pivot block (actuator) 520. A mechanism is provided for moving the lock pin 521 formed at the tip of the pivot block 520 up and down to release the engagement relationship between the lock pin 521 and the cage.

  The bail 510 includes a grip portion 511, a shoulder portion 512 embedded in the pivot block 520, and a main body portion 513 that connects both of them with a wire frame. A cam 514 is formed by bending a wire at the center of the shoulder 512, and the shoulder 512 is embedded in the pivot groove 522 of the pivot block 520 together with the cam 514. The pivot block 520 performs a seesaw motion around the pivot arm 523. When the bail 510 is rotated, the cam 514 is rotated in the pivot groove 522, and the tip of the cam 514 pushes the portion of the pivot block 520 in front of the pivot arm 523 outward with respect to the receptacle 530. And

  Since the pivot block 520 performs a seesaw motion, the lock pin 521 formed behind the pivot block 520 is pulled toward the receptacle 530, and the latch between the lock pin 521 and the cage is released. In order to prevent the pivot block 520 from being separated from the receptacle 530, the optical transceiver 500 includes a support piece 550 attached to the tip of the case 540 (the tip on the receptacle 530 side), and the pivot block 520 is attached to the support piece 550. The pivot block 520 does not come off in order to always support from below.

  FIG. 9 is a diagram showing an optical transceiver having a cage insertion / removal mechanism described in Patent Document 2. This insertion / removal mechanism also includes a bail 610 and an actuator 620. The bail 610 simply moves the actuator 620 back and forth. The rotation movement is converted into the back-and-forth movement of the actuator 620 or the up-and-down movement of the engagement protrusion 630 engaged with the engagement hole 711 formed in the cage 700. There is no. A wedge 621 is formed at the tip of the actuator 620, and this wedge 621 is accommodated in a pocket 640 formed in the optical transceiver 600 when the optical transceiver 600 is engaged with the cage 700.

One side of the pocket 640 has a slope, and when the optical transceiver 600 is slightly pulled out of the cage 700 by picking the bale 610, the wedge 621 slides on the slope of the pocket 640, and the tip of the wedge 621 is the latch piece 710 of the cage 700. Push up. As a result, the engagement between the engagement protrusion 630 of the optical transceiver 600 and the engagement hole 711 of the latch piece 710 of the cage 700 is released. A spring piece 622 is formed on the actuator 620, and the steady position thereof is defined by the elastic force at a position where the wedge 621 is stored in the pocket 640.
US Pat. No. 6,439,918 US Patent Application Publication No. 2003/142917

In recent years, it has been proposed that these pluggable optical transceivers are densely arranged three-dimensionally to construct a hub for optical communication. For example, an optical communication hub having 32 to 64 channels can be configured by arranging 16 optical transceivers with a 1 cm square cross-sectional area horizontally and 2 to 4 vertically. In such a device, when an optical transmission cable is inserted into an adjacent pluggable optical transceiver, when the optical transceiver is pulled out of the cage, the adjacent optical transceiver and the optical transmission cable become an obstacle, and the optical transceiver bale is damaged. The optical transceiver cannot be rotated, and the optical transceiver cannot be easily removed.
Further, in the above-described insertion / removal mechanism, the components constituting the insertion / removal mechanism are easily detached from each other, and it is necessary to prevent the components from being detached by providing an actuator support piece or the like at the tip of the case.

  The present invention has been made in view of the above circumstances, and an optical transceiver having a novel insertion / removal mechanism between an optical transceiver and a cage, particularly in a host device in which optical transceivers are densely arranged, can be applied to the cage. It is an object of the present invention to provide an optical transceiver having an insertion / removal mechanism that can be inserted / removed and in which components are not easily detached from each other.

An optical transceiver according to the present invention is an actuator having a receptacle on which an end of an optical transmission cable is detachably mounted, and an engagement protrusion that is removably engaged with an engagement hole formed in a bottom portion of a cage of a host device. And a bale that is rotatably attached to the receptacle and that allows the engagement protrusion of the actuator to be inserted into and removed from the engagement hole of the cage by a turning operation , and the receptacle is provided at a lower portion of the receptacle. The actuator is pivotally supported so that a seesaw motion is possible, and has a mounting shaft to which the bale is rotatably mounted. The bail includes a pair of legs, and the mounting shaft is inserted into the legs. The actuator has an extension portion extending from the insertion hole, the extension portion of the bail having an insertion hole, capable of rotating around the mounting shaft; It has a contact portion that, when the bale movement rotates, the actuator is seesaw motion by sliding between the extended portion of the bail and the contact portion of the actuator, formed in the cage by the seesaw motion The engagement protrusion of the actuator is inserted into and removed from the engagement hole thus formed, and can be inserted into and removed from the cage of the host device. The actuator is made of resin, and the actuator is When the seesaw movement is performed in a direction in which the engagement protrusion is detached from the engagement hole, a plate spring part that resists the seesaw movement is integrally provided, and the engagement protrusion is inserted into the engagement hole by the plate spring part. so as to bias toward, the contact portion of the actuator, the contact surface of the extension tip of the bail to slide in contact is constituted, the contact surface includes a recess The extension tip the recess is characterized by being capable of holding the bale in position by engaging.

Wherein the plate spring portion of the actuator fixed to the receptacle, said actuator may be prevented from engaging the shaft support which is pivotally supported on the receptacle is disengaged.
Further, the leaf spring portion, said actuator when secured to said receptacle, about the axis of the seesaw motion, to the receptacle side opposite to the side where the engaging projection of the actuator is formed It is also preferable to apply an urging force to press.

  According to the optical transceiver of the present invention, even when the optical transceivers are densely arranged, the target optical transceiver can be easily inserted into and removed from the cage of the host device.

  FIG. 1 is an overhead view of a pluggable optical transceiver (hereinafter simply referred to as a transceiver) according to the present invention. The transceiver 1 includes a bail 10, an actuator 20, a receptacle 30, a cover 40, a substrate 50, a frame 60, and It is composed of a ground finger 70. Hereinafter, the direction in which the receptacle 30 is provided is the front side of the transceiver, and the opposite side, that is, the side on which the plug 51 is formed on the substrate 50 is the rear side. Further, the side that is visible in FIG. 1 and the side to which the actuator 20 is attached is the lower side of the transceiver, and the opposite side, the side that is hidden in FIG. This vertical direction follows the vertical direction when the transceiver 1 is inserted into a cage (not shown).

  The rear side is inserted into the cage, and a plug 51 formed at the rear end of the transceiver 1 engages with an electrical connector in the cage. Thereby, the electronic circuit of the host device and the circuit on the substrate 50 of the transceiver 1 are electrically connected. The front surface 2 of the receptacle 1 on the front side of the transceiver 1 opens in the face panel of the host device, and the end of the optical transmission cable (optical cable) is detachably attached to the receptacle 30 of the transceiver 1 through the opening.

  A bale 10 and an actuator 20 are attached to the receptacle 30. The actuator 20 has an engagement protrusion 23a that is detachably engaged with an engagement hole formed in the bottom of the cage of the host device. Further, the bail 10 is rotatably mounted on the receptacle 30, and the engaging protrusion 23a of the actuator 20 is inserted into and removed from the engaging hole of the cage by a rotating operation. The receptacle 30 is attached in front of the cover 40.

  The cover 40 is attached to the frame 60 that holds the substrate 50 having the plugs 51. From the front end of the cover 40, the engagement protrusion 23a of the actuator 20 and the ground finger 70 protrude. The transceiver 1 is held in the cage by the engagement protrusion 23a being engaged with an engagement hole formed in the cage. On the other hand, when the transceiver 1 is inserted into the cage, the ground finger 70 is in electrical contact with the inner surface of the cage to reinforce the ground potential and secure one heat dissipation path for the cage.

  In the present invention, the actuator 20 and the receptacle 30 are formed of a resin mold, and the veil is disclosed in two forms: a resin veil 10 and a metal bail 110 (see FIG. 5). The frame 60 has a structure in which a single metal plate is formed by cutting, bending, or tapping, and welding, adhesion, or the like is not used. Hereinafter, the configurations of the bail 10, 110, the actuator 20, and the receptacle 30 according to the present invention will be described.

a. Actuator FIG. 2 (A) is a lower overhead view of the actuator according to the present invention, FIG. 2 (B) is an upper overhead view thereof, and FIG. 2 (C) is a side view. The actuator 20 is composed of three main parts: a main body part 21, a fulcrum part 22, and an engaging part 23. The main body 21 includes a contact portion 21a on both sides and a connecting portion 21d that connects the contact portions 21a, and integrally includes a leaf spring portion 24 that extends rearward from the connecting portion 21d.

  Each contact portion 21a has a plurality of surfaces that are smoothly connected to each other on its upper surface, and has contact surfaces formed in two steps outward. Here, the inner groove portion is the groove 21b, and the outer raised portion is the guide edge 21e. A first recess 21f and a second recess 21g are formed on the contact surface. The protrusions (see FIG. 4) of the legs of the bail 10 can be accommodated in the recesses 21g to temporarily hold the movement of the bale 10.

  The front of the connecting portion 21d is loosely recessed, and by widening the gap between the receptacles of other transceivers located below, the ease of grasping the bale 10 when the transceivers are densely arranged is improved. ing. The leaf spring portion 24 is formed with an angle with respect to the main body portion 21. That is, the leaf spring portion 24 is formed so that the rear end side thereof is lifted at an angle of about 3.5 ° with respect to the reference surface 21k with respect to the lower surface of the receptacle 30 of the main body portion 21. When the actuator 20 is set in the receptacle 30 shown in FIG. 3, the leaf spring portion 24 is set while being bent. The stress repelling the bending is absorbed by the shaft support portion of the receptacle 30 that receives the shaft 22a of the seesaw motion of the actuator 20 (the shaft 22a and the shaft support portion will be described later), but the rear end of the shaft 22a and the leaf spring portion 24. Since the position is offset, this stress acts as a force that pushes up the tip side of the actuator 20 upward, that is, a force that pushes the tip side against the receptacle 30. Due to this upward pressing force, the protrusion 21 j formed on the reference surface 21 k of the actuator 20 makes point contact with the lower surface of the receptacle 30.

  The distal end of the leaf spring portion 24 extending rearward from the connecting portion 21d passes through the fulcrum portion 22 and reaches the engaging portion 23. And the horizontal cross section extended upwards at the front-end | tip is equipped with the T-shaped protrusion 24a. As will be described later, the protrusion 24a of the leaf spring portion 24 is accommodated in a pocket portion formed in the central partition wall of the receptacle 30, thereby restricting the movement of the actuator 20 in the front-rear direction. Further, the leaf spring portion 24 is closely contacted and fixed to the receptacle 30, so that when the remaining portion of the actuator 20 performs a seesaw motion around the fulcrum portion 22, a force that resists the seesaw motion is applied to the actuator 20. By this leaf spring portion 24, the engagement protrusion 23a of the actuator 20 is urged toward the engagement hole of the cage. Therefore, even if the bail 10 is operated to cause the actuator 20 to perform the seesaw motion, when the bail 10 is released, the actuator 20 is automatically activated by the elastic force of the leaf spring portion 24 as shown in FIGS. ) State.

  A shaft 22 a having a substantially semi-cylindrical shape is formed on the fulcrum portion 22. The shaft 22 a is set on the shaft support portion of the receptacle 30. The inside of the shaft support portion is also processed into a substantially semi-cylindrical shape, and the seesaw motion of the actuator 20 is enabled by the shaft 22a smoothly rotating inside the shaft support portion.

  At the tip of the engagement portion 23, an engagement protrusion 23a that engages with the engagement hole of the cage is formed. The rear side surface of the engaging protrusion 23a is formed as an inclined surface, and the front side surface is formed as a surface that is steep (rises substantially perpendicularly from the main body) with respect to the engaging portion 23 main body. When the transceiver 1 is inserted into the cage, it is inserted while jumping up the latch piece of the cage by this inclined surface, and when it is once inserted, the steep surface and the engagement hole in the latch piece are securely engaged with each other. A structure that is not easily released, and a mechanism that is not easily released without an insertion / removal mechanism as in the present invention are provided. Further, a groove 23 b having a slope is formed on the upper surface of the rear end portion of the engaging portion 23. This is because when the seesaw motion is induced in the actuator 20, the rear end of the engaging portion 23 is drawn toward the receptacle 30, but when the actuator 20 is drawn in, the central partition wall of the receptacle 30 forms the groove 23 b. The operating width of the seesaw movement is increased by being housed inside.

  FIG. 2C is a side view of the actuator 20. The contact portion 21a is formed with a first recess 21f, a second recess 21g, a flat portion 21h, and a circular arc portion 21i continuously from the front side. When the projections of the 10 leg portions come into contact with each other and slide, the seesaw motion can be induced in the actuator 20 in conjunction with the rotation of the bail 10. The arc portion 21 i forms a concave surface with respect to the rotation center of the bail 10.

b. Receptacle FIG. 3A is a front overhead view of the receptacle 30, and FIG. 3B is a rear overhead view of the receptacle 30. The receptacle 30 is formed by resin molding. The receptacle 30 is divided into a receptacle part 31, a mounting part 32, and a connection part 33 in order from the front. The receptacle 31 has two transmission / reception openings 31a and 31b on the front side, and an end (optical connector) of an optical cable is inserted into the opening. The internal dimensions (width and depth) of the openings and the interval between the openings are defined by the optical connector standard.

  An attachment shaft 31 c (for example, a substantially cylindrical protrusion) is provided on the outer surface of the receptacle portion 31, and this is the rotation center of the bail 10. Further, a shaft support portion 31d that supports a shaft 22a that is a rotation shaft of the seesaw motion of the actuator 20 is formed on the lower surface, and the inner surface shape thereof is a semi-cylindrical shape so as to trace the outer surface shape of the shaft 22a of the actuator 20. Has been processed. At the rear end of the receptacle part 31, a step part 31 e that is one step higher than the others is formed, and the side surface of the bail 10 abuts on the step part 31 e to restrict the rotational movement of the bail 10. The step portion 31 e provides a function of a rotation stopper for the bail 10.

  The mounting unit 32 has two spaces 32a and 32b, and a transmission subassembly (Transmitting Optical Sub-Assembly: TOSA) and a receiving subassembly (Receiving Optical Sub-Assembly: ROSA) are mounted in the spaces. The spaces 32a and 32b are formed by a side wall 32c and a central partition wall 32d, and a plurality of concave surfaces and protrusions for mounting TOSA / ROSA are formed inside the space. A pocket 32e is formed at the front end of the central partition wall 32d. A protrusion 24a formed at the rear end of the leaf spring portion 24 of the actuator 20 is accommodated in the pocket 32e. In accordance with the cross-sectional shape of the protrusion 24 a, the inner surface shape of the pocket 32 e is such that the depth thereof gradually decreases toward the front and smoothly connects to the bottom surface of the receptacle portion 31.

  Further, the bottom surface of the receptacle portion 31 on both front sides of the central partition wall 32d forms an inclined surface 32f, and assists the seesaw motion around the shaft 22a of the actuator 20 attached to the receptacle 30. Further, the inclined surface 32f facilitates the attachment of the actuator 20 to the receptacle 30. A protrusion 32g is formed on the outer surface of the side wall 32c, and the protrusion 32g engages with the opening on the side surface of the cover 40 and is assembled.

  The connecting portion 33 is used when the ground finger 70 is assembled to the receptacle 30. As shown in FIG. 1, even after the cover 40 is assembled to the receptacle 30, the ground finger 70 protrudes outward from the gap between the two, and directly contacts the inner surface of the cage when the transceiver 1 is set in the cage. To ensure ground potential. On the other hand, since the inside of the transceiver 1 contacts the outer surface of the TOSA / ROSA, the outer surface of the TOSA / ROSA can be made equipotential with the case ground. Here, the receptacle 30 is made of resin. On the other hand, in the structure according to this transceiver, the ground finger 70 is in direct contact with the cage, so that the stability of the EMI shield and the ground potential is basically achieved.

c-1. Bale of First Form FIG. 4A is an upper front view of the bale according to the first form, and FIG. 4B is a lower rear view of the same. The bail 10 has a so-called U-shaped configuration having a pair of leg portions 11 and a connecting portion 12 that connects the leg portions 11. The bale 10 according to this embodiment is formed by resin molding. Two concavities 12a and 12b are formed in the connecting portion 12 of the bail 10, and when the receptacle 30 of the connecting portion 12 of the bail 10 is set at a predetermined position, the two openings 31a for transmitting / receiving the receptacle 30 are provided. , 31b. The upper surface is also provided with a recess 12c for attaching a label.

  Each of the pair of leg portions 11 is provided with an insertion hole 11a through which the attachment shaft 31c of the receptacle 30 is inserted, and the bail 10 can rotate around the attachment shaft 31c. Moreover, the leg part 11 has the extension part 11b extended from the insertion hole 11a. When the bail 10 rotates, the actuator performs seesaw motion by engagement between the contact portion 21a of the actuator 20 and the extension portion 11b of the bail 10, and the seesaw motion causes the engagement of the actuator 20 to the cage engagement hole. The mating protrusion 23a is inserted and removed.

More specifically, a protrusion 11c is provided inside the tip (front end) of the extension portion 11b, and the protrusion 11c has a composite shape having a guide edge 11d and a groove 11e. The guide edge 11d fits in the groove 21b of the contact portion 21a of the actuator 20, the groove 11e slides on the guide edge 21e of the actuator 20, the actuator 20 performs seesaw motion, and the engagement of the actuator 20 to the engagement hole of the cage. The mating protrusion 23a is inserted and removed.
Further, due to the combined shape of the projections 11c of the extension portion 11b, the bail 10 is securely assembled with the actuator 20, and even when the bail 10 is rotated, the leg portion 11 expands outward and the actuator No more than 20 That is, even if the leg portion 11 of the bail 10 tries to spread outward, the guide edge 11d of the protrusion 11c is prevented from coming into contact with the inner surface of the guide edge 21e of the actuator 20 and spreading.

  The rear end 11f of the leg portion 11 has a linear shape and abuts against the step portion 31e of the receptacle 30 at its initial position. Here, the initial position corresponds to the time when the connecting portion 12 of the bail 10 is at the uppermost position of the receptacle 30. Further, the bottom surface 11g of the extension portion 11b of the leg portion 11 abuts on the step portion 31e of the receptacle 30 when the bail 10 is rotated to the maximum, and as a result, the rotational movement of the bail 10 is restricted.

  Moreover, the leg part 11 is a substantially L-shape, and the short side is located in the front-back direction in the initial position, and the long side is located in the up-down direction. By adopting such a shape, even when it is not possible to touch the connecting portion 12 of the bail 10, the upper surface 11 h of the short side (extension portion 11 b) of the leg portion 11 is pushed down to rotate the bail 10. The main body 21 of the actuator 20 can be pushed down.

c-2. Bale of Second Form FIG. 5A is an upper front view of the bale according to the second form, and FIG. 5B is a lower rear view of the same. The bale 110 is formed by bending a metal plate material such as stainless steel. Similar to the veil 10 described above, the bail 110 is also a U-shaped member including a pair of leg portions 111 and a connecting portion 112 that connects the leg portions. The leg portion 110 is provided with an insertion hole 111a through which the attachment shaft 31c of the receptacle 30 is inserted, and the bail 110 can rotate about the attachment shaft 31c.

  Moreover, the leg part 111 has the extension part 111b extended from the insertion hole 111a, and the protrusion 111c is provided inside the front end of this extension part 111b. The protrusion 111 c is formed by drawing (punching), and the side surface of the protrusion 111 c slides on the guide edge 21 e of the actuator 20. In the bail 111 of this embodiment, a structure that fits in the groove 21b of the actuator 20 is not formed. Further, the rear end 111f of the leg portion 111 hits the stepped portion 31e of the receptacle 30 at the initial position, and the bottom surface 111g of the extension portion 111b of the leg portion 111 hits the stepped portion 31e at the maximum rotation time of the bale 110, thereby rotating the bail 110. Is also the same as the bail 10 of the first embodiment.

The leg portion 11 of the bail 10 shown in FIG. 5A has a substantially L shape, and its short side is positioned in the front-rear direction and the long side is positioned in the up-down direction at the initial position. By adopting such a shape, even when it is not possible to touch the connecting portion 12 of the bail 10, the upper surface 11 h of the short side (extension portion 11 b) of the bale is pushed down to rotate the bail 10. And the body portion 21 of the actuator 20 can be pushed down.
Note that the leg portion 111 of the bail 110 shown in FIG. 5B is also substantially L-shaped as described above, but the short side of the leg portion is formed on the upper surface 111h of the short side (extension portion 111b) of the leg portion 111. There may be provided a bent portion 111i formed by bending the upper surface of the inside. By providing the bent portion 111i, the area of the short side upper surface 111h is increased, and the short side upper surface 111h can be easily pushed down. Further, the bent portion 111i is not necessarily provided on both the leg portions 111. When the optical transceiver 1 according to the present invention is inserted into a cage mounted at a high density and used, when both bent portions 111 are provided with the bent portions 111i, the legs of adjacent transceivers are touched. Is assumed. This situation can be avoided by providing only one of them.

d. Bale Rotation and Actuator Seesaw Motion FIGS. 6A to 6E are a series of diagrams illustrating the relationship between the rotation motion of the bail 10 and the seesaw motion of the actuator 20 according to the first embodiment. In FIG. 6A, the bail 10 is in an initial state. That is, the connecting portion 12 of the bail 10 is located above the receptacle 30 and opens the two openings 31a and 31b of the receptacle 30. At this time, the protrusion 11c of the extension 11b of the bail 10 is at the forefront of the contact surface of the actuator 20, and is received and held in the first recess 21i. Further, the engaging protrusion 23a protrudes to the outermost side and is received in the engaging hole of the cage.

  From this state, when the bail 10 is rotated forward by pushing down the upper surface 11h of the short side of the bail, the protrusion 11c of the extension 11b of the bail 10 is once in the position of the actuator 20 at the position shown in FIG. 2 fits in the recess 21g. Thereby, it is possible to hold the bale 10 in a predetermined position, and the bale 10 can be adapted for so-called double decker. At this position, the engaging protrusion 23a is drawn closer to the receptacle 30 than the position shown in FIG.

  When the bail 10 is further rotated, the protrusion 11c of the extension portion 11b slides in contact with the flat portion 21h of the contact surface of the actuator 20 (FIG. 6C). The distance from the contact point between the protrusion 11c of the extension portion 11b and the flat portion 21h to the rotation center (attachment shaft 31c) of the actuator 20 gradually decreases in conjunction with the rotation of the bail 10. Accordingly, the protrusion 11c of the extension portion 11b pushes the main body portion 21 of the actuator 20 outward, and the engagement protrusion 23a is gradually drawn toward the receptacle 30 by the seesaw motion, and finally, in the latch piece of the cage. The engagement state with the engagement hole is released (FIG. 6D).

Even if the bail 10 is further rotated from this position, the projection 11c of the extension portion 11b only slides on the arc portion 21i that draws an arc with respect to the mounting shaft 31c that is the rotation center of the bail 10. Therefore, the actuator 20 is not pushed out much more than that. Finally, as shown in FIG. 6E, the bottom surface 11g of the extension portion 11b abuts against the step portion 31e of the receptacle 30 to restrict the rotation of the bail 10.

  Since the cage is formed of a thin metal plate, the individual dimensional variation is large. Further, even if the cage is initially formed with a prescribed size, the external dimensions are distorted by repeated insertion / extraction of the transceiver. Accordingly, it is not possible to precisely define at which position on the contact surface of the actuator the protrusion of the extension portion of the bail is released, but at least the rearmost portion of the flat portion 21h of the contact surface, That is, in the connection part with the circular arc part 21i, the engagement protrusion 23a must be located in the disengagement position where the engagement protrusion 23a is detached from the engagement hole of the cage.

  Further, even if the engaging portion 23 of the actuator 20 performs a series of operations in accordance with the rotation of the bail 10 as described above, the leaf spring portion 24 is maintained rigidly fixed to the receptacle 30. . Therefore, the force when returning the bail 10 from the position shown in FIG. 6E to the initial position shown in FIG. 6A by the elastic force of the leaf spring portion 24 releases the engagement. It becomes lighter than the force from 6 (A) to FIG. 6 (E). In particular, when the protrusion 11c of the extension portion 11b is on the arc portion 21i, the bail 10 automatically recovers the position of FIG. 6D by the elastic force of the leaf spring portion 24.

  Further, in the structure of the actuator 20 according to the present invention, a structure for restricting the operation of pushing down the front end 21c of the actuator 20 is not formed. Although the leaf spring portion 24 always acts to press the main body portion 21 of the actuator 20 against the receptacle 30 side, the actuator 20 can be operated to perform seesaw motion by operating the actuator front end 21c.

  This is very effective in the following cases. That is, if the cage is tightly attached to the host device and the transceiver is inserted into the cage around the target cage with the optical connector / optical cable installed, these optical connectors / optical cables become obstacles. In some cases, the target transceiver bale cannot be operated. When the transceiver is removed from the cage, the bail 10 is positioned above the receptacle 30 (the initial state in FIG. 6A). The bale 10 cannot be operated when another cage is installed immediately above the target transceiver and the transceiver is inserted in the cage directly above.

  Even in such a case, the front surface of the receptacle 30 is in a state in which the optical connector is removed and opened, and a sufficient gap is secured to operate the front end 21 c of the actuator 20. By pushing down below the front end 21c, the seesaw motion of the actuator 20 can be performed, and the engagement protrusion 23a at the rear end of the actuator 20 can be pulled to the transceiver body side, and the target transceiver can be removed from the cage. it can.

e. Assembly of Receptacle, Bale, and Actuator Next, a method for assembling the bale and actuator of the transceiver of the present invention to the receptacle will be described with reference to FIGS. 7 (A) to 7 (D).

  First, the bail 10 is attached to the transceiver body in which the receptacle 30, the TOSA / ROSA, the substrate 50, the frame 60, and the cover 40 ground finger 70 are assembled (FIGS. 7A and 7B). Since both the leg portions 11 of the bail 10 can be easily expanded by the elastic force of the connecting portion 12, the mounting shaft 31c of the receptacle 30 is engaged with the insertion hole 11a while expanding the leg portion 11 (FIG. 7 ( B)).

  As shown in FIG. 7C, the actuator 20 is then slid on the bottom surface from the front side of the receptacle 30 to set the shaft 22 a of the actuator 20 on the shaft support 31 d of the receptacle 30. At this time, the protrusion 24 a at the tip of the leaf spring portion 24 of the actuator 20 is received in the pocket 32 e formed in the central partition wall of the receptacle 30. The rearward movement of the actuator 20 is restricted by the shaft support portion 31d, and the forward movement is restricted by the engagement between the protrusion 24a of the leaf spring portion 24 and the pocket 32e of the receptacle 30, so that the actuator 20 is restrained by the receptacle 30. On the other hand, it does not slide horizontally (in a direction parallel to the bottom surface). Therefore, it is possible to prevent the shaft support portion 31d from being disengaged.

  Further, regarding the vertical movement of the actuator 20, in addition to the shaft support portion 31d covering the shaft 22a (FIG. 7D), a protrusion 21j on the upper surface of the body portion 21 of the actuator 20 (FIG. 2B). Therefore, the leaf spring portion 24 is always slightly bent, and a force that pushes up the main body portion 21 of the actuator 20 by the elastic force of the leaf spring portion 24 acts. Therefore, the actuator 20 is restricted from sliding in the vertical direction. Only the seesaw motion around the shaft 22a is allowed. The bail 10 and the actuator 20 are assembled to the receptacle 30 by the above procedure, and as described with reference to FIGS. 6 (A) to 6 (E), the bail 10 rotates and moves to the tip of the actuator 20. The transceiver can be inserted into and removed from the cage by moving the formed engaging protrusion 23a up and down.

It is a downward perspective view of the optical transceiver concerning the present invention. 2A is a lower perspective view of the actuator according to the present invention, FIG. 2B is an upper perspective view thereof, and FIG. 2C is a side view thereof. FIG. 3 (A) is a lower perspective view of the receptacle according to the present invention, and FIG. 3 (B) is an upper perspective view of the same. 4A is an upper perspective view of an example of a bale according to the present invention, and FIG. 4B is a lower perspective view of the same. FIG. 5 (A) is an upper perspective view of another example of the bail according to the present invention, and FIG. 5 (B) is a lower perspective view thereof. It is a side view which shows the mode of a motion of the veil and actuator which concern on this invention continuously. It is a downward perspective view which shows a mode when the bale and actuator which concern on this invention are assembled | attached with respect to a receptacle. It is a perspective view for demonstrating the insertion / extraction mechanism of the optical transceiver described in patent document 1 (US Patent 6,439,918 specification). It is a figure for demonstrating the insertion / extraction mechanism of the optical transceiver described in patent document 2 (US Patent application publication 2003/142917 specification).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Transceiver, 2 ... Receptacle front, 10, 110 ... Bale, 11, 111 ... Leg part, 11a, 111a ... Insertion hole, 11b, 111b ... Extension part, 11c, 111c ... Projection, 11d ... Guide edge, 11e ... Groove 11f, 111f ... rear end of legs, 11g, 111g ... bottom surface of extension, 11h, 111h ... top surface of extension, 111i ... bent portion, 12, 112 ... connecting portion, 12a, 12b ... recess, 12c ... recess, 20 ... Actuator, 21 ... body part, 21a ... contact part, 21b ... groove, 21c ... actuator front end, 21d ... connecting part, 21e ... guide edge, 21f ... first recess, 21g ... second recess, 21h ... flat part, 21i... Arc portion, 21j... Projection, 21k... Reference plane, 22... Support point portion, 22a... Shaft, 23 ... Engagement portion, 23a. 24a ... projection, 30 ... receptacle, 31 ... receptacle part, 31a, 31b ... opening, 31c ... mounting shaft, 31d ... shaft support part, 31e ... step part, 32 ... mounting part, 32a, 32b ... space, 32c ... side wall, 32d: Central partition, 32e: Pocket, 32f: Inclined surface, 32g ... Projection, 33 ... Connection, 40 ... Cover, 50 ... Substrate, 51 ... Plug, 60 ... Frame, 70 ... Grounding finger.

Claims (3)

A receptacle to which the end of the optical transmission cable is detachably attached;
An actuator having an engaging projection removably engaged with an engaging hole formed in the bottom of the cage of the host device ;
A bale that is rotatably attached to the receptacle and that allows the engagement protrusion of the actuator to be inserted into and removed from the engagement hole of the cage by a rotation operation;
With
The receptacle has a mounting shaft on which the actuator is pivotally supported so that a seesaw movement is possible at a lower portion of the receptacle, and the bale is rotatably mounted .
The bail includes a pair of legs, the legs having an insertion hole through which the attachment shaft is inserted, and capable of rotating around the attachment shaft, and from the insertion hole. Have an extension to extend,
The actuator has a contact portion with which the extension of the bale contacts;
When the bail rotates, the actuator performs a seesaw motion by sliding between the contact portion of the actuator and the extension portion of the bail, and the engagement hole formed in the cage by the seesaw motion. An optical transceiver in which the engagement protrusion of the actuator is inserted and removed, and thereby can be inserted into and removed from a cage of a host device,
The actuator is made of resin, and integrally includes a leaf spring portion that resists the seesaw motion when the actuator performs a seesaw motion in a direction in which the engagement protrusion is detached from the engagement hole. The portion is adapted to urge the engaging protrusion toward the engaging hole ,
The contact portion of the actuator is configured to have a contact surface on which the tip of the extension of the bail contacts and slides. The contact surface includes a recess, and the tip of the extension is engaged with the recess. An optical transceiver characterized in that it can be held in place.   The said leaf | plate spring part of the said actuator is fixed to the said receptacle, The engagement of the axial support part which is supporting the said actuator on the said receptacle is prevented from releasing. Optical transceiver.   When the actuator is fixed to the receptacle, the leaf spring portion is attached to the receptacle by pressing the opposite side of the actuator to the side on which the engagement protrusion is formed, with the seesaw motion axis as the center. 3. The optical transceiver according to claim 1, wherein power is applied.

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