JP4718972B2 - Transceiver module - Google Patents

Description

  The present invention relates to a transceiver module, which has a function of transmitting and receiving data, and relates to a transceiver module that is mounted on an information processing apparatus such as a server apparatus and is in use.

  One LAN (Local Area Network) is an Ethernet (Ethernet (registered trademark)) LAN which is a bus type LAN. The Ethernet LAN is constructed by installing a server device having a function of transmitting and receiving data and connecting a signal transmission path thereto. This system such as a LAN is as long as several tens km when the data transmission distance is long, and as short as about 10 m when the distance is short, and the scale varies depending on the user. Therefore, a plurality of types of transceiver modules, which are modules having functions for transmitting and receiving data, are prepared according to the communication distance so that the user's needs can be flexibly handled. It is configured to have a plurality of mounting portions and assembled by mounting a desired transceiver module on the mounting portion. Further, when there is a change in the data transmission distance, the transceiver module can be removed from the mounting portion and another transceiver module can be mounted. Several conventions have been established for transceiver modules so that any type of transceiver module can be installed in the transceiver module mounting, ie, compatible between the transceiver modules.

  One convention is that the pulling sleeve that surrounds the connector is pulled so that the locking pawl protruding from the side of the transceiver module is retracted into the housing.

  FIGS. 1A and 1B show a configuration considered by the applicant of the present application in the middle of reaching the invention of the present application. FIG. 1A shows a state where the transceiver module 10 is inserted in the X1 direction and is attached to the transceiver module mounting portion 21 of the server device 20, and FIG. 1B shows the transceiver module 10 as a transceiver module of the server device 20. The state at the time of taking out from the mounting base 21 is shown.

  11 is a housing of the transceiver module, 12 is a pull sleeve, and 13a is a locking claw. Reference numeral 12 a denotes a wedge, which is integral with the pull sleeve 12 and is located in the space 11 a of the housing 11. The locking claw 13a is formed by bending one end of the leaf spring member 13, and has a triangular shape. The leaf spring member 13 is bent into a U-shape and incorporated in the space portion 11a, and the locking claw 13a protrudes from the side surface of the housing 10 and engages with the locking port 21a of the transceiver module mounting base 21. Is latched. A cable connector (not shown) is connected to the connector on the X2 end side of the transceiver module 10.

  As shown in FIG. 1B, when the pull sleeve 12 is pulled in the X2 direction, the wedge portion 12a pushes the locking claw 13a to bend the leaf spring member 13, and the locking claw 13a is retracted into the housing 11. , The latch is released, and the transceiver module 10 is pulled out from the server device 20.

The locking claw 13a is formed by bending a part of the leaf spring member 13, and the strength of the base portion 13b tends to be weak. For this reason, for example, when the cable connector is pulled accidentally, as shown in FIG. 2A, the tip of the locking claw 13a hits the end of the locking port 21a and the locking claw 13a The force F1 acts relatively, and the counterclockwise moment M1 acts on the base portion 13b having a low strength, and the locking claw 13a is bent at the base portion 13b, as shown in FIG. Thus, it was found that the locking claw 13a is tilted and the lock becomes incomplete.

It is an object of the present invention to provide a transceiver module capable of performing a more complete lock made in view of the above points.

Therefore, in order to solve the above problems, the present invention has a rectangular parallelepiped shape, and is provided in a metal housing having one side on the front side and the other side on the tip side in the insertion direction in the longitudinal direction. A data transmission / reception unit for transmitting and receiving data, an external connection connector on the front side of the housing, a contact part on the distal side in the insertion direction of the housing, and a latch mechanism;
A transceiver module that is inserted into an information processing device with the contact portion at the top, is latched with respect to the information processing device by the latch mechanism, and is used by connecting the contact portion to an interface of the information processing device In
The latch mechanism is
A locking claw member provided in the housing so as to be slidable in the width direction so that a part protrudes from a side surface thereof, and having a first cam portion on the front side in the longitudinal direction ;
A spring member for protrusion that is located on the inner side in the width direction of the locking claw member and biases the locking claw member in a direction protruding from the side surface of the housing;
A pull sleeve that is provided on the front side of the housing so as to surround the external connection connector is provided integrally. When the pull sleeve is pulled, it acts on the first cam portion of the locking claw member. A second cam portion that pulls the locking claw member into the housing against the protruding spring member;
The locking claw member and the protruding spring member are separate parts.

  According to the present invention, since the latching claw member and the protruding spring member are separate parts, a latch mechanism with high mechanical strength can be realized.

  Next, an embodiment of the present invention will be described.

[Outline of server device and transceiver module]
3 and 4 show a state in which the transceiver module 50 according to the first embodiment of the present invention is being mounted on the transceiver module mounting base 21 of the server device 20.

  X1-X2 is the longitudinal direction of the transceiver module 50 (depth direction of the server device 20), Y1-Y2 is the width direction of the transceiver module 50 (width direction of the server device 20), and Z1-Z2 is the height (thickness) of the transceiver module 50. ) Direction (height direction of the server device 20). The X2 side is the front, and the X1 side is the insertion direction tip.

  The server device 20 has a plurality of transceiver module insertion openings 23 on its front panel 22, and a substantially U-shaped transceiver module mounting base 21 is provided facing each insertion opening 23. The mounting base 21 is mounted on the mother board 24. The mounting base 21 has a box shape with an open top surface, a side plate having a locking port 21a, an upper end of the side plate serving as a guide rail portion 21b, and an interface connection connector 25 at the back of the server device. It is connected to 20 interfaces.

  The transceiver module 50 has a configuration in which a data transmission / reception assembly 51 that transmits and receives data is incorporated in a module housing 90, has a rectangular parallelepiped shape that is long in the X1-X2 direction, has a pull sleeve 170 on the X2 side, and X2 The balanced transmission connector plug 80 is provided on the side, and the card edge contact portion 61 is provided on the X1 side. By using the connector plug 80 for balanced transmission, the transceiver module 50 has a function capable of high-speed communication with a maximum transfer rate of 10 Gbit, although the communication distance is limited to a short distance, and the Ethernet (registered trademark) specification is used. Satisfied. Since the transceiver module 50 does not include a photoelectric conversion unit, the cost is reduced accordingly.

  The server device 20 applied to a system for performing high-speed communication with a short communication distance inserts the transceiver module 50 in the X1 direction along the transceiver module mounting base 21 through the transceiver module insertion port 23, and inserts the card edge contact portion 61 into the card module. The transceiver module 50 is assembled by connecting to the interface connector 25, latching as will be described later, and mounting the transceiver module 50. A balanced transmission connector plug 80 protrudes from the front panel 22.

The balanced transmission cable connector 40 extending from another device is connected to the balanced transmission connector plug 80 of the server device 20 by being locked to a later-described locking hole member 85, and the server device 20 and the other device are connected. Connected, a short-range high-speed communication system is constructed. Since the cost of the transceiver module 50 is low, the cost for constructing this short-distance high-speed communication system is low compared to the prior art.
[Configuration of transceiver module 50 (excluding latch mechanism)]
FIG. 5 shows the transceiver module 50 in an exploded view. FIG. 6 is a cross-sectional view enlarged by a vertical plane SVI in FIG. 3, and FIG. 7 is a cross-sectional view enlarged by a vertical plane SVII in FIG.

  In the data transmission / reception assembly 51, an LSI 70 is mounted in the center of the printed circuit board 60, a balanced transmission connector plug 80 is mounted on the X2 side end of the printed circuit board 60, and a terminal is connected to the X1 side of the printed circuit board 60. The card edge contact portions 61 are arranged side by side. The LSI 70 has a function of transmitting and receiving data, and is surface-mounted on the printed circuit board 60 by a ball grid array terminal on the lower surface.

  As shown in FIG. 6 and FIG. 7 in an enlarged manner, the balanced transmission connector plug 80 includes a pair of a plus signal terminal and a minus signal terminal (both not shown) in the insulating plug housing 81 and a ground terminal. In this configuration, a large number of 82 are installed side by side. On the X2 side of the balanced transmission connector plug 80, a plug portion 83 whose periphery is covered with a shield member 84 and a locking hole member 85 on the Y1, Y2 side are provided. The balanced transmission connector plug 80 is positioned by supporting a part of the housing 81 on the printed circuit board 60, fitting the leg portion 81a of the housing 81 into the hole of the printed circuit board 60, and lined up on the X2 side. The terminal portion 86 is soldered to the corresponding terminal portion of the printed circuit board 60. The number of pairs is 16, and 8 sets are assigned for reception and the remaining 8 sets are assigned for transmission.

  The plug housing 81 has protrusions 81b and 81c on both sides of the upper surface, protrusions 81d and 81e on both sides of the lower surface, and an overhanging portion 81f on the X1 side of the upper surface.

  As shown in FIG. 5, the module housing 90 has a configuration in which an upper housing half 91 and a lower housing half 110 that are both made of aluminum are combined.

  The upper housing half 91 has a large number of heat radiation fins 92 on the upper surface. The radiation fins 92 are long in the Y1-Y2 direction, and are arranged in the X1-X2 direction. Reference numerals 93 and 94 denote connecting portions, which connect the adjacent radiation fins 92 at the Y1 side end and the Y2 side end. The upper surface of the radiation fin 92 and the upper surfaces of the connecting portions 93 and 94 are the same surface. A pedestal 95 for attaching the printed circuit board 60 is formed inside. On the X2 side, a flange half portion 96 and a cover half portion 97 are provided. The cover half portion 97 has a rib portion 98 that protrudes inward along the leading edge, has protrusions 100 and 101 on the inner surface, and has a step portion 102 on the X2 side. A shallow heat-dissipating sheet recess 103 is formed on the substantially central back surface of the upper housing half 91, that is, the back surface of the portion where the heat dissipating fins 92 are formed, and the convex portion 104 is formed on the ceiling surface of the recess 103. A plurality of are formed. Further, the flange half portion 96 is formed with a notch portion 105 through which the rod portion of the pull sleeve passes.

  The lower housing half 110 has a flange half portion 111 and a cover half portion 112 on the X2 side. The cover half portion 112 has a rib portion 113 projecting inward along the leading edge, and has protrusions 114 and 115 on the inner surface. The lower housing half 110 is formed with latch mechanism incorporating portions 116 and 117 on the inner Y2 and Y1 sides closer to the X2 side, and a guide groove long in the X1-X2 direction on the outer surface of the side plate. 118 is formed.

  As shown in FIG. 4, in the data transmission / reception assembly 51, a part of the printed circuit board 60 is fixed to the back surface of the upper housing half 91 by screws 120 to the pedestal portion 95, and another part of the printed circuit board 60 is attached. A module comprising the upper housing half 91 and the lower housing half 110, which is sandwiched between the upper housing half 91 and the lower housing half 110, and is fastened together with screws that secure the lower housing half 110 to the upper housing half 91. It is accommodated in the housing 90. Further, the cover half portions 97 and 112 are combined to form the cover portion 122, and the flange half portions 96 and 111 are combined to form the flange portion 119.

  The balanced transmission connector plug 80 is accommodated in the cover portion 122 formed by the cover half portions 97 and 112, and the plug portion 83 is exposed to the X2 side from the cover portion 122. The card edge contact portion 61 faces the X1 end of the module housing 90. The heat radiating sheet 130 is contained in the heat radiating sheet recess 103 and is sandwiched between the upper surface of the LSI 70 and the lower surface of the upper housing half 91. A plurality of convex portions 104 are pressed against the heat radiating sheet 130 rather than a flat surface, and the load pressing the LSI 70 in the Z2 direction via the heat radiating sheet 130 is prevented from becoming excessive. As a result, it is possible to prevent an excessive stress from acting on a connection portion of the LSI 70 to the printed circuit board 60 or a crack from occurring, thereby impairing the electrical connection.

  Referring to FIGS. 6 and 7, attention is paid to the balanced transmission connector plug 80 portion.

  Looking at the Z1-Z2 direction, the protrusions 100 and 101 and the protrusions 114 and 115 contact the protrusions 81b and 81c and the protrusions 81d and 81e, respectively, and are balanced at two locations on the Y1 side and the Y2 side, respectively. A transmission connector plug 80 is sandwiched. Since the protrusion 100 and the protrusion 81b and the like are formed with high dimensional accuracy, the position of the balanced transmission connector plug 80 in the Z1-Z2 direction with respect to the module housing 90 is determined with high accuracy.

  In the X1-X2 direction, as shown in FIG. 6, the rib portions 98 and 113 lock a part of the balanced transmission connector plug 80, and the step portion 102 locks the overhang portion 81f and presses it. It has been.

  Therefore, when the transceiver module 50 is attached to the server device 20 and when the balanced transmission cable connector 40 is connected, the force in the X1 direction applied to the balanced transmission connector plug 80 is caused by the projecting portion 81f hitting the stepped portion 102. It is received by the module housing 90. Further, when the transceiver module 50 is pulled out from the server device 20 and when the balanced transmission cable connector 40 is pulled out, the force in the X2 direction applied to the balanced transmission connector plug 80 is the X2 side of the balanced transmission connector plug 80. The end is brought into contact with the rib portions 98 and 113 and is received by the module housing 90. Therefore, useless force does not act on the soldered portion of the terminal portion 86 to the printed circuit board 60.

  Further, as shown in FIG. 7, a metal-made sponge-like gasket 140 is sandwiched between the shield member 84 and the upper housing half 91 between the projecting portions 81b, 81c, and the metal-like sponge-like gasket. 141 is sandwiched between the shield member 84 and the lower housing half 110 between the protrusions 81d and 81e, and measures against EMI (electro-magnetic interference) are taken.

  Here, attention is paid to the heat radiation fin portion on the upper surface of the transceiver module 50. When the connecting portions 93 and 94 do not exist, in the process of inserting the transceiver module 50 shown in FIG. 4 into the server device 20, if the X2 side of the transceiver module 50 is pulled up in the Z1 direction, the radiation fins As shown by a two-dot chain line in FIG. 4, 92 hits a portion facing the insertion port 23 of the front panel 22, and further insertion becomes impossible. Therefore, it is necessary to perform the work with care so that the radiating fins 92 do not hit the front panel 22. However, in the present embodiment, since the connecting portions 93 and 94 are present, the X2 side of the transceiver module 50 is pulled up in the Z1 direction in the process of inserting the transceiver module 50 shown in FIG. Even if the connecting portions 93 and 94 hit the portion of the front panel 22 that faces the edge on the Z1 side of the insertion slot 23, the movement of the transceiver module 50 in the Z1 direction is restricted, and the heat radiating fins 92 are connected to the front panel. Therefore, the operation of inserting the transceiver module 50 into the server device 20 and the operation of pulling the transceiver module 50 out of the server device 20 are easy.

The transceiver module 50 is inserted into the server device 20 while the guide grooves 118 on both sides are guided by the guide rail portions 21b of the transceiver module mounting base 21.
[Configuration and Operation of Latch Mechanism of Transceiver Module 50]
FIG. 8 shows a latch mechanism 150 that latches the transceiver module 50 in a state where it is mounted on the server device 20. FIG. 9 is an enlarged view of the latch claw member 151 in FIG. FIG. 10 shows a cross section taken along line XX in FIG. FIG. 11 shows the latch mechanism 150 in an exploded manner.

  The latch mechanism 150 is provided on the Y2 side and the Y1 side of the transceiver module 50. Since each has the same configuration, the mechanism on the Y2 side will be described, and the description of the mechanism on the Y1 side will be omitted.

  As shown in FIG. 11, the latch mechanism 150 includes a latch claw member 151 and a coil spring 160. The latch claw member 151 and the coil spring 160 are separate members.

  The latch claw member 151 is an independent part, has a claw shape and has a sufficient strength, has a locking surface 152 on the X2 side, and is parallel to the locking surface 152 on the X1 side. The first cam portion 154 protrudes to the Z1 side on the X2 side on the Z1 side surface. The surface on the Z1 side has an overhanging portion 155 that protrudes toward the X1 side and an overhanging portion 156 that protrudes toward the X2 side. The overhanging portion 156 includes a part of the cam portion 154. A coil spring accommodating groove 157 is provided on the Z2 side surface. The coil spring accommodating groove 157 penetrates to the Y1 side.

  As shown in FIG. 5, the pull sleeve 170 includes a pull sleeve main body 171, a lower metal plate member 180, and a coil spring 181. The pull sleeve body 171 includes an inverted U-shaped pull sleeve portion 172 including a horizontal plate portion 172a and vertical plate portions 172b and 172c on both sides, and a vertical plate portion 172b and 172c on both sides of the pull sleeve portion 172 in the X1 direction. And a rod portion 173 protruding to the surface. The outer peripheral surface of the pull sleeve portion 172 has a concave shape so that the fingertip is easily caught when the pull sleeve portion 172 is grasped and pulled. The rod portion 173 has a rectangular cross section, and has a wedge-shaped second cam portion 174 and a projection portion 175 protruding on the Z2 side on the Z2 side surface thereof as shown in FIG. . A concave portion 176 is provided on the Z1 side surface of the rod portion 173.

  The pull sleeve main body 171 covers the upper side and the horizontal side of the cover portion 122, and the lower metal plate member 180 is laid across the vertical plate portions 172b and 172c. The pull sleeve main body 171 and the lower metal plate member 180 forms a square frame 185, which surrounds the cover portion 122 and is slidably fitted in the X2 direction. Since the lower side is the metal plate member 180, the square frame 185 has a shorter dimension H1 in the Z1-Z2 direction, and a height dimension H2 of the flange portion 119 of the transceiver module 50 becomes shorter.

  The rod portion 173 enters the module housing 90 through the notch portion 105 (opening 119a of the flange portion 119) of the flange half portion 96.

  As shown in FIGS. 10 and 11, the latch mechanism built-in portion 116 of the lower housing half 110 has a groove portion 190 extending in the Y1-Y2 direction, and extends in the X1-X2 direction across the groove portion 190. And a groove portion 191. The groove 190 accommodates the latch claw member 151 and the coil spring 160. The groove portion 191 accommodates the rod portion 173 of the pull sleeve main body 171. An end of the groove portion 190 in the Y2 direction is an opening 192. The portion of the side wall of the lower housing half 110 that faces the opening 192 forms stoppers 193 and 194. The upper housing half 91 has a groove portion 195 facing the groove portion 191 and a rib portion 196. The groove portion 195 accommodates the Z1 side portion of the rod portion 173 and the coil spring 181. The rib portion 196 is fitted to the X2 side of the recess 176, and the coil spring 181 is provided between the rib portion 196 and the X1 side wall of the recess 176.

  The latch claw member 151 is fitted in the groove 190 together with the coil spring 160 housed in the groove 157, and is slidable in the Y1-Y2 direction. The overhang portions 155 and 156 are located on the bottom surface of the groove portion 191. The rod portion 173 is accommodated in the groove portion 191 so as to cover the upper side of the latch claw member 151. The portion on the Z1 side of the rod portion 173 is fitted in the groove portion 195 together with the coil spring 181 that is housed in the recess 176. The rod portion 173 is slidable in the X1-X2 direction. The coil spring 181 is disposed between the X1 side end of the recess 176 and the X2 side end of the groove portion 195.

  Normally, the latch mechanism 150 is in the state shown in FIGS. The pull sleeve 170 is moved in the X1 direction by the spring force of the coil spring 181, the square frame 185 surrounds the cover portion 122, and the cam portion 174 is positioned closer to the X1 side than the cam portion 154 of the latch claw member 151. is doing. The latch claw member 151 is moved in the Y2 direction by the spring force of the coil spring 160, the overhang portions 155 and 156 are locked to the stoppers 193 and 194, and protrude outward from the opening 192.

  When the transceiver module 50 is inserted into the server device 20 as shown in FIG. 4, the latch claw member 151 is once pushed into the module housing 90, and the transceiver module mounting base 21 is locked as shown in FIG. The transceiver module 50 is latched by the server device 20 so as to protrude into the mouth 21a.

  When extracting the transceiver module 50 from the server device 20, the operator grasps the square frame 185 of the pull sleeve 170 by hand and pulls it strongly in the X2 direction. By this operation, the coil spring 181 is bent and the square frame 185 is moved in the X2 direction. As shown in FIG. 13, the cam portion 174 pushes the cam portion 154 of the latch claw member 151, and the latch claw member 151 is turned into the coil spring. It is moved in the Y1 direction against 160 and retracted into the module housing 90, and the latch is released. Also, as shown in FIG. 12, the projection 175 hits the end of the groove 191 on the X2 side, and the operator pulls the pull sleeve 170 in the X2 direction, and the force is transmitted to the module housing 90 via the rod 173. The module 50 is moved in the X2 direction, the card edge contact portion 61 is pulled out from the interface connection connector 25, and the transceiver module 50 is pulled out from the server device 20.

  When the operator removes his / her hand from the square frame 185 of the pull sleeve 170, the pull sleeve 170 is moved to the original position in the X1 direction by the coil spring 181.

  Next, in a state where the transceiver device 50 is mounted, for example, the balanced transmission cable connector 40 is erroneously pulled, and the latch mechanism 150 is applied to the transceiver module 50 in the direction of coming out of the server device 20. This state will be described with reference to FIG.

  The latch claw member 151 has a sufficient strength and is fitted in the groove 190, and the surface 152 and the surface 153 are opposed to the side surfaces 190a and 190b of the groove 190, respectively.

  When a force in the direction of pulling out from the server device 20 is applied to the transceiver module 50, a force F1 in the X1 direction is applied to the Y2 side portion of the latch claw member 151 by the edge of the locking port 21a of the transceiver module mounting base 21, and the latch A counterclockwise moment M <b> 1 acts on the claw member 151 around the point P <b> 2 that hits the side surface 190 b of the surface 153.

  Here, the latch claw member 151 has sufficient strength, is fitted in the groove 190, and the surface 152 and the surface 153 are opposed to the side surfaces 190a and 190b of the groove 190, respectively. The surface 152 hits the side surface 190a, the surface 153 hits the side surface 190b, and is firmly supported at two locations P1 and P2 that are separated in the X1-X2 direction. Therefore, the latch claw member 151 itself is not deformed, and the latch claw member 151 is not inclined.

  The moment M1 also acts when the operator pulls the pull sleeve 170 in the X2 direction by hand to extract the transceiver module 50 from the server device 20.

  Here, the cam portion 154 of the latch claw member 151 is disposed on the X2 side of the latch claw member 151. Therefore, when the operator manually pulls the pull sleeve 170 in the X2 direction, the position P3 where the force F2 for pushing the latch claw member 151 in the Y1 direction acts is the same as the X1-X2 direction upper locking surface 152. The force F2 acts in a direction to cancel the moment M1, and the latch claw member 151 does not twist the groove 190, and the movement of the latch claw member 151 in the Y1 direction in the groove 190 is smooth. Done.

  The same mechanism as described above is provided on the Y1 side, and when the pull sleeve 170 is pulled, the Y2 side latch claw member 151 and the Y1 side latch claw member 151 are simultaneously drawn into the module housing 90.

  The latch mechanism 150 can also be applied to a transceiver module that includes an optical connector on the front side instead of the balanced transmission connector plug 80 and includes a photoelectric conversion unit therein.

  15 and 16 show a transceiver module 50A according to the second embodiment of the present invention. FIG. 15 also shows a state where the transceiver module 50A is disassembled. Compared with the transceiver module 50 shown in FIGS. 3 and 4, the transceiver module 50A is different in part of the latch mechanism, and the other parts are the same as those of the transceiver module 50, and the illustration thereof is omitted.

  The latch mechanism 150A has a pull sleeve 170A shown in FIG. As shown in FIGS. 16 and 17, the pull sleeve 170 </ b> A includes a pull sleeve main body 171 </ b> A and a shield plate member 200, and does not have the coil spring 181.

  The pull sleeve main body 171A is a synthetic resin molded part for cost reduction and weight reduction, and protrudes in the X1 direction from a square frame-shaped pull sleeve portion 172A and portions on both sides of the pull sleeve portion 172A. It consists of two rod parts 173A. The rod portion 173A has a quadrangular prism shape, and has a slit 177A and a recess 179A in the middle. The slit 177A is cut into a U shape from the outside on both sides of the pull sleeve body 171A. A core 178A having a square cross section is left behind the slit 177A (see FIG. 18). The recess 179A is formed on the surface on the Z1 side of the rod portion 173A in the portion on the X1 side from the position of the slit 177A.

  As shown in FIG. 18, the shield plate member 200 is a metal plate piece, a main body portion 201, a mountain-shaped leaf spring portion 202 on the upper side of the main body portion 201, and a U-shaped leaf spring on the lower side of the main body portion 201. Part 203. The main body 201 is plate-shaped and has a size corresponding to the notch 105 (opening 119a of the flange 119) of the flange half 96, and has a square notch 201a corresponding to the core 178A on one side. In addition, convex portions 201b and 201c are formed on a portion closer to the Y2 side than the notch 201a and near the corner of the notch 201a. The leaf spring portion 202 has a mountain shape that is bent in the X1 direction from the upper end of the main body portion 201 and is convex in the Z1 direction. The U-shaped leaf spring portion 203 is U-shaped by folding back a portion below the main body portion 201 to the X2 side.

  The shield plate member 200 has the main body portion 201 fitted into the slit 177A of the rod portion 173A of the pull sleeve main body 171A, the notch 201a is fitted into the core portion 178A, and the convex portions 201b and 201c are press-fitted into the slit 177A. In this state, it is fixed in a direction perpendicular to the axis of the rod portion 173A. The mountain-shaped leaf spring portion 202 is housed in the recess 179A. The U-shaped leaf spring portion 203 protrudes from the rod portion 173A to the Z2 side.

  FIG. 19 shows a module housing 90 formed by combining an upper housing half 91 and a lower housing half 110. The flange portion 119 has a rectangular opening 119a on the Y1 and Y2 sides. The opening 119a is an opening through which the base portion of the rod portion 173A passes, and has a shape corresponding to the cross-sectional shape of the base portion of the rod portion 173A.

  When the upper housing half 91 and the lower housing half 110 are combined, the pull sleeve 170A fits between them, the cover half portions 97 and 112 are fitted inside the pull sleeve portion 172A, and a flange is formed. The half portion 96 is assembled so that the cutout portion 105 of the half portion 96 is fitted to the base portion of the rod portion 173A. As shown in FIG. 16, the rod portion 173 </ b> A fits inside the module housing 90, the mountain-shaped leaf spring portion 202 contacts the ceiling surface of the upper housing half 91, and the Z-shaped end of the U-shaped leaf spring portion 203. Is in contact with the bottom surface of the lower housing half 110, and the tip of the U-shaped leaf spring portion 203 is in contact with the vertical rib 119c inside the lower housing half 110.

  Next, the function and operation of the shield plate member 200 of the latch mechanism 150A will be described.

  First, the shield plate member 200 has a shielding function. That is, in a state where the transceiver module 50A is mounted on the transceiver module mounting base 21 of the server device 20, the module housing 90 is at the frame ground potential, and thus the shield plate member 200 is also at the frame ground potential. Further, as shown in FIG. 15, the main body 201 and the U-shaped leaf spring 203 are located immediately behind the opening 119a. Therefore, the shield plate member 200 acts to limit electromagnetic waves generated inside the transceiver module 50A from leaking outside through the opening 119a, and has an EMI prevention function for the opening 119a.

  Secondly, the shield plate member 200 functions as a spring that returns the pulled pull sleeve 170A to its original position. When the operator grasps the pull sleeve main body 171A and pulls it strongly in the X2 direction, the U-shaped leaf spring portion 203 is bent, the pull sleeve 170A is moved in the X2 direction, and the lock is released in the same manner as described above. The transceiver module 50A is pulled out from the server device 20. When the operator removes his hand from the pull sleeve main body 171A, the U-shaped leaf spring portion 203 is elastically restored, and the pull sleeve 170A is returned to the original position in the X1 direction.

  It is also possible to manufacture the pull sleeve 170A by insert molding the shield plate member 200.

  FIG. 20 shows a transceiver module 50B according to the third embodiment of the present invention. Compared to the transceiver module 50 shown in FIG. 3 and FIG. 4, the transceiver module 50B is a low-profile, low-profile type with a height dimension H10 smaller than the height dimension H2 of the transceiver module 50, and the flange portion 119B. The metal spring type gasket 250 is provided on the upper surface and the lower surface of the back side portion, and the cylindrical gasket 260 is provided on the left and right surfaces of the back side portion of the flange portion 119B. Other parts are the same as those of the transceiver module 50, and the illustration thereof is omitted.

  As shown in FIGS. 20 and 23, the flange portion 119B of the module housing 90B of the transceiver module 50B includes a Z1 surface side flange portion 119BZ1, a Z2 surface side flange portion 119BZ2, a Y1 surface side flange portion 119BY1, and a Y2 surface side. It is the structure which consists of flange part 119BY2. The Y2 surface side flange portion 119BY2 has a configuration in which a Y2 surface side flange half portion 96Y2 and a Y2 surface side flange half portion 111Y2 are arranged side by side. The Y1-side flange portion 119BY1 has the same configuration as the Y2-side flange portion 119BY2.

  Since the low type is thin, as shown in FIG. 21 (A), the height dimension h of the Z1 surface side flange portion 119BZ1 is low, and the dimension of the portion where the sponge gasket can be locked is short. The square-frame sponge gasket cannot be used. Therefore, a metal spring type gasket 250 invented by the present inventor and shown in FIG. 22 is used.

  The metal spring type gasket 250 includes a strip portion 251 that is long in the Y1-Y2 direction, and a plurality of leaf spring portions 252 that are inclined at a predetermined pitch p from the strip portion 251 in the X1 direction in the Z1 direction. , And a plurality of latch portions 253 formed along the X1 side edge of the belt portion 251. The pitch p is narrow enough not to allow the passage of electromagnetic waves. The leaf spring part 252 has an S-shaped part 252a and a tip part 252b on the tip side. The latch portion 253 is located between the adjacent leaf spring portions 252, and is a main body portion 253a bent in the Z2 direction, and a leaf spring portion formed by folding back in the Z1 direction on the X2 side from the lower end of the main body portion 253a. 253b and a pair of lug portions 253c and 253d which are bent in the X2 direction from the lower end from both sides of the main body portion 253a.

  The metal spring type gasket 250 is attached to the upper housing half 91B and the lower housing half 111B. A metal spring type gasket attached to the upper housing half 91B is indicated by reference numeral 250Z1, and a metal spring type gasket attached to the lower housing half 111B is indicated by reference numeral 250Z2.

  As shown in FIGS. 21 (A), (B) and FIG. 25, the metal spring type gasket 250Z1 locks the leading end portion 252b of each leaf spring portion 252 to the slit 255 of the Z1 surface side flange portion 119BZ1, By pushing the latch portion 253 into the slit 256 of the upper housing half 91B, the leaf spring portion 253b that has passed through the slit 256 is locked by self-locking the back surface of the upper housing half 91B, and the lug portions 253c and 253d are slit. 256 is just engaged and fixed. That is, the metal spring type gasket 250Z1 has a large number of leaf spring portions 252 along the Z1 surface side flange portion 119BZ1 along the Z1 surface side flange portion 119BZ1 in the portion immediately on the X1 side of the Z1 surface side flange portion 119BZ1 of the upper surface of the upper housing half 91B. It is attached in a state aligned in the Y2 direction. All the leaf springs 252 are in a state where the tip portions can be elastically deformed in the Z2 direction.

  As shown in FIG. 25, a metal spring type gasket 250Z2 is attached to the lower housing half 111B in the same manner as described above.

  As shown in FIG. 23, 260Y2 is a cylindrical gasket, and the upper half is fitted into the recess 265 on the back surface side of the Y2 surface side flange half portion 96Y2, and the recess 266 on the back surface side of the Y2 surface side flange half portion 111Y2. The lower half is fitted and attached to the back surface side of the Y2 surface side flange portion 119BY2. A cylindrical gasket 260Y1 is also attached to the back side of the Y1-side flange portion 119BY1.

  As shown in FIG. 24, the transceiver module 50B is inserted and mounted through the transceiver module insertion slot 23 of the front panel 22 of the server device 20. The relationship between the transceiver module 50B and the insertion slot 23 is as shown in FIGS. That is, the square insertion port 23 has bent edges 28Z1, 28Z2, 28Y1, and 28Y21 that are bent toward the inside of the server device 20 on each side. At the final stage of mounting the transceiver module 50B, the leaf spring portion 252 and the cylindrical gaskets 260Y1, 260Y2 are bent against the bent edge portion 28Z1 and the like. Therefore, as shown in FIG. 25, all the leaf spring portions 252 of the metal spring type gasket 250Z1 are pressed against the bent edge portion 28Z1, and all the leaf spring portions 252 of the metal spring type gasket 250Z2 are bent edge portions. It hits 28Z2. As shown in FIG. 26, the cylindrical gasket 260Y1 is pressed against the bent edge portion 28Y1, and the cylindrical gasket 260Y2 is pressed against the bent edge portion 28Y2. Thus, the portion along the edge of the insertion port 23 is well shielded, and the portion along the entire circumference of the edge of the insertion port 23 is in a state where EMI countermeasures are taken.

  27A to 27E show modifications of the latch portion 253. FIG. 27A and 27B has a structure in which a part of the latch portions 253A and 253B is elastically restored when it is inserted into the slit 256, and the rear surface of the housing half is locked to be self-locked. 27 (C), (D), and (E), the latch portions 253C, 253D, and 253E are provided with portions 253Cx, 253Dx, As shown by 253Ex, it is structured to be bent and fixed.

  FIG. 28 shows an exploded view of a transceiver module 50C according to a fourth embodiment of the present invention. In FIG. 28, the pull sleeve and the latch mechanism are omitted. 29 and 30 are enlarged views of the portion on the X2 side in FIG. FIG. 33 shows a fixed state of the balanced transmission connector plug 80C in the cover portion 122C of the module housing 90C. FIG. 33 is a view from the Y2 side, and FIG. 34 is a view from the Y1 side. In each figure, the same reference numerals are given to the parts corresponding to the constituent parts shown in FIG. 5, and the same reference numerals with the suffix C attached to the different parts.

  The transceiver module 50C is different from the transceiver module 50 shown in FIG. 5 in the fixing state of the balanced transmission connector plug 80C in the cover portion 122C of the module housing 90C. FIG. 35 is a diagram schematically showing a portion where the housing 81C of the balanced transmission connector plug 80C is fixed by the cover portion 122C.

  The housing 81C is a substantially rectangular parallelepiped as shown in FIG. 34, and has a long width dimension W and a short height dimension H. For this reason, when the housing 81C is fixed inside the cover portion 122C, the rotation about the Z1-Z2 axis is easily restrained, but the rotation about the Y1-Y2 axis is difficult to restrain.

  The balanced transmission connector plug 80C differs from the balanced transmission connector plug 80 shown in FIG. 5 in a part of the housing 81C. As shown in FIG. 29, the side surface 81CY2 on the Y1 side of the insulating housing 81C has an inverted trapezoidal groove 300Y2 cut from the upper surface 81CZ1 and a trapezoidal groove 301Y2 cut from the lower surface 81CZ2, and FIG. As shown in FIG. 3, the side surface 81CY1 on the Y1 side of the housing 81C has an inverted trapezoidal groove 301Y1 cut from the upper surface 81CZ1 and a trapezoidal groove 301Y1 cut from the lower surface 81CZ2. Both side surfaces 81CY1 and 81CY2 of the housing 81C have a substantially square shape.

  In the direction of X1-X2, the inverted trapezoidal grooves 300Y2, 300Y1 are at the position P1 of the X1-X2 axis, the trapezoidal grooves 301Y2, 301Y1 are at the position P2 on the X2 side from the position P1, and the inverted trapezoidal grooves 300Y2, 300Y1 and the trapezoidal grooves 301Y2 and 301Y1 are separated by a distance L in the direction of X1-X2.

  As shown in FIG. 28, the module housing 90C has a configuration in which an upper housing half 91C and a lower housing half 110C are combined, and a cover portion 122C is different from the module housing 90 shown in FIG. The cover portion 122C refers to a portion covering and covering the housing 81C of the balanced transmission connector plug 80C. The cover portion 122C is formed by combining a cover half portion 97C and a cover half portion 112C.

  The upper housing half 91C and the lower housing half 110C are different from the upper housing half 91 and the lower housing half 110 shown in FIG. The cover half portion 97C has inverted trapezoidal protrusions 310Y2 and 310Y1 corresponding to the inverted trapezoidal grooves 300Y2 and 300Y1, and the cover half portion 112C corresponds to the trapezoidal grooves 301Y2 and 301Y1. Trapezoidal protrusions 320Y2 and 320Y1 are formed.

  As shown in FIG. 30, the inverted trapezoidal protrusion 310Y2 rises on the inner surface of the side plate 97Cb at the corner formed by the top plate portion 97Ca and the side plate 97Cb of the cover half portion 97C, and extends in the Z2 direction from the top plate portion 97Ca. Sticks out. As shown in FIG. 29, the inverted trapezoidal protrusion 310Y1 rises on the inner surface of the side plate 97Cc at the corner formed by the top plate portion 97Ca and the side plate 97Cc of the cover half portion 97C, and extends in the Z2 direction from the top plate portion 97Ca. Sticks out.

  As shown in FIG. 30, the trapezoidal protrusion 310Y2 rises on the inner surface of the side plate 112Cb at the corner formed by the bottom plate portion 112Ca and the side plate 112Cb of the cover half portion 112C, and protrudes in the Z1 direction from the bottom plate portion 112Ca. Yes. As shown in FIG. 29, the trapezoidal protrusion 310Y1 rises on the inner surface of the side plate 112Cc at the corner formed by the bottom plate portion 112Ca and the side plate 112Cc of the cover half portion 112C, and protrudes in the Z1 direction from the bottom plate portion 112Ca. Yes.

  In the direction of X1-X2, the inverted trapezoidal protrusions 310Y2 and 310Y1 are at the position P1, the trapezoidal protrusions 320Y2 and 320Y1 are at the position P2 on the X2 side from the position P1, and the inverted trapezoidal protrusions 310Y2 and 310Y1 and the trapezoidal protrusion 320Y2 and 320Y1 are separated by a distance L in the direction of X1-X2.

  31A and 31B show the inverted trapezoidal groove 300Y2 (300Y1) and the inverted trapezoidal protrusion 310Y2 (310Y1) in an enlarged manner facing each other. 32A and 32B show the trapezoidal groove 301Y2 (301Y1) and the trapezoidal protrusion 320Y2 (320Y1) in an enlarged manner facing each other. The opening angle of the inverted trapezoidal groove 300Y2 (300Y1) and the trapezoidal groove 301Y2 (301Y1) is α1, the opening angle of the inverted trapezoidal protrusion 310Y2 (310Y1) and the trapezoidal protrusion 320Y2 (320Y1) is α2, and α2 is from α1. Is slightly larger, α2> α1, and the inverted trapezoidal protrusion 310Y2 (310Y1) has an inverted trapezoidal groove 300Y2 (300Y1) as shown in FIGS. 31B and 32A with the protrusions superimposed on the grooves. The trapezoidal protrusion 320Y2 (320Y1) is press-fitted into the trapezoidal groove 301Y2 (301Y1).

  As shown in FIGS. 33, 34 and 35, the portion of the housing 81C of the balanced transmission connector plug 80C is sandwiched between the cover half portion 97C and the cover half portion 112C, and is encased by the cover portion 122C. The housing 81C is fixed to the cover portion 122C at two locations on the Y2 side and two locations on the Y1 side.

  Q1 is the height of the upper surface 81CZ1 of the housing 81C, and Q2 is the height of the lower surface 81CZ2 of the housing 81C.

  Looking at the Y2 side, as shown in FIG. 33, on the upper surface 81CZ1 side of the housing 81C, the inverted trapezoidal protrusion 310Y2 is press-fitted into the inverted trapezoidal groove 300Y2, and the portion BY2 is in the X1-X2 direction. And the movement in the Z1 direction are restricted and fixed. The lower surface 81CZ2 side of the housing 81C is press-fitted with a trapezoidal protrusion 320Y2 fitted into the trapezoidal groove 301Y2, and the movement in the X1-X2 direction and the movement in the Z2 direction are restricted and fixed at the part CY2. . The fixed portion BY2 having the height Q1 and the fixed portion CY2 having the height Q2 are shifted by a distance L in the longitudinal direction (X1-X2 direction) of the transceiver module 50C. The fixed part BY2 and the fixed part CY2 are two different positions on the oblique line 330Y2, and are positions close to the diagonal of the Y2 side surface 81CY2.

  Looking at the Y1 side, as shown in FIG. 34, on the upper surface 81CZ1 side of the housing 81C, the inverted trapezoidal protrusion 310Y1 is press-fitted into the inverted trapezoidal groove 300Y1, and the region BY1 is in the X1-X2 direction. And the movement in the Z1 direction are restricted and fixed. The lower surface 81CZ2 side of the housing 81C is press-fitted with a trapezoidal protrusion 320Y1 fitted into the trapezoidal groove 301Y1, and the movement in the X1-X2 direction and the movement in the Z2 direction are restricted and fixed at the part CY1. . The fixed portion BY1 having the height Q1 and the fixed portion CY1 having the height Q2 are shifted by a distance L in the longitudinal direction (X1-X2 direction) of the transceiver module 50C. The fixing part BY1 and the fixing part CY1 are two different positions on the oblique line 330Y1, and are positions close to the diagonal of the Y1 side surface 81CY1.

  Therefore, as shown in FIG. 35, the fixed portion of the housing 81 </ b> C has a corner on the surface S <b> 1 passing through a position between X <b> 1 and Z <b> 1 and a position between X <b> 2 and Z <b> 2 among the eight corners 1 to 8. It is a position near 1, 5, 4, 8. The fixing portions BY1, BY2 on the upper surface side of the housing 81C and the fixing portions DY1, DY2 on the lower surface side of the housing 81C are shifted by a distance L in the longitudinal direction (X1-X2 direction) of the transceiver module 50C.

  Here, it is assumed that the distal end side of the balanced transmission connector plug 80C is moved so as to bend in the Z1-Z2 direction as shown by arrows in FIGS. The balanced transmission connector plug 80 </ b> C rotates about the fixed portion having the height Q <b> 1 or the fixed portion having the height Q <b> 2 according to the direction in which it is twisted to move and tilt.

  When a force FZ2 in the Z2 direction acts on the distal end side of the balanced transmission connector plug 80C, the balanced transmission connector plug 80C tries to tilt around the fixed portions CY2 and CY1, but the fixed portion BY2 and BY1 function as stoppers, the distance L is the length of the arm from the center of rotation to the stopper, the functions of the fixed parts BY2 and BY1 as stoppers act effectively, and for balanced transmission in the cover part 122C The tilting movement of the connector plug 80C is effectively limited.

  When a force FZ1 in the Z1 direction is applied to the distal end side of the balanced transmission connector plug 80C, the balanced transmission connector plug 80C tries to tilt around the fixed portions BY1 and BY2, but the fixed portion CY1 and CY2 function as stoppers, the distance L is the length of the arm from the center of rotation to the stopper, and the functions as the stoppers of the fixed parts CY1 and CY2 work effectively, for balanced transmission in the cover part 122C. The tilting movement of the connector plug 80C is effectively limited.

  Therefore, as shown in FIG. 3, operations for connecting the balanced transmission cable connector 40 to the balanced transmission connector plug 80C of the server device 20 and removing the balanced transmission cable connector 40 from the balanced transmission connector plug 80C are rough. Even if this is done, the balanced transmission cable connector 40 does not move so as to rotate within the XZ plane inside the cover portion 122C. Therefore, unnecessary stress does not act on the portion where the terminal portion 86 is soldered to the corresponding terminal portion of the printed circuit board 60, and the soldered portion is not damaged or the soldered portion is not peeled off. .

  The fixing parts BY2, CY2 and the fixing parts BY1, CY1 are several times apart from the distance L on the Y1-Y2 axis, and are inside the cover part 122C of the housing 81C of the balanced transmission connector plug 80C. The rotational movement around the Z1-Z2 axis is well constrained.

  In addition, the fixed part of the housing 81C is a position near the corners 2, 3, 6, 7 on the surface S2 passing through the position between X1 and Z2 and the position between X2 and Z1 in FIG. That is, the positions indicated by AY1, AY2, DY1, and DY2 in FIGS. 33 and 34 may be used. Further, the fixed part of the housing 81C is located at a position near all the corners 1 to 8, that is, positions indicated by AY1, AY2, BY1, BY2, CY1, CY2, DY1, and DY2 in FIGS. 33 and 34. It may be.

It is a figure which shows the latch mechanism of the structure which the applicant of this application considered in the middle of reaching the invention of this application. It is a figure for demonstrating the problem of the latch mechanism of FIG. It is a perspective view which shows the transceiver module which becomes Example 1 of this invention. FIG. 4 is a cross-sectional view of the transceiver module of FIG. 3. FIG. 4 is an exploded perspective view of the transceiver module of FIG. 3. FIG. 4 is an enlarged cross-sectional view of a front side portion of the transceiver module taken along a vertical plane SVI in FIG. 3. FIG. 4 is an enlarged cross-sectional view of a front side portion of the transceiver module taken along a vertical plane SVII in FIG. 3. FIG. 4 is an enlarged plan view showing a latch mechanism in FIG. 3. FIG. 9 is an enlarged plan view showing a latch claw member and a portion related thereto in FIG. 8. It is sectional drawing which follows the XX line in FIG. It is a figure which decomposes | disassembles and shows the latch mechanism of FIG. It is a figure which shows the latch mechanism of a state when pulling a pull sleeve. It is a figure which shows the state of the latch claw member when pulling a pull sleeve, and the part relevant to this. It is a figure for demonstrating the state of a latching claw member when the force of the direction pulled out acts on a transceiver module. It is a perspective view which also shows the state which decomposed | disassembled the transceiver module which becomes Example 2 of this invention. FIG. 16 is a cross-sectional view showing a pull sleeve portion of the latch mechanism in FIG. 15. It is a perspective view which expands and shows a pull sleeve. It is a figure which shows the attachment state to the rod part of a shield board member and a shield board member. It is a perspective view which shows a module housing. It is a perspective view which shows the transceiver module which becomes Example 3 of this invention. It is sectional drawing which shows the part to which the metal spring type gasket is attached in FIG. It is a figure which shows a metal spring type | mold gasket. It is a figure which shows the attachment method of a cylindrical gasket. It is a perspective view which shows the state of the insertion slot vicinity of the installed transceiver module. It is a vertical side view which shows the state of the insertion slot vicinity of the installed transceiver module. It is a cross-sectional top view which shows the state of the insertion opening vicinity of the transceiver module with which it has mounted | worn. It is a figure which shows the modification of the latch part of a metal spring type | mold gasket. It is a disassembled perspective view which shows the transceiver module which becomes Example 4 of this invention. It is a figure which expands and shows the part which fixes the connector plug for balanced transmission in FIG. It is a figure which expands and shows the part which fixes the connector plug for balanced transmission in FIG. 28, and sees from the Y1 side. It is a figure which expands and shows an inverted trapezoidal groove and an inverted trapezoidal protrusion corresponding to each other. It is a figure which expands and shows a trapezoid groove and a trapezoid protrusion corresponding to it. It is a figure which expands and shows the part which the connector plug for balanced transmission is fixed, seeing from the Y2 side. It is a figure which expands and shows the part to which the connector plug for balanced transmission is fixed, seeing from the Y1 side. It is a figure which shows roughly the position of the fixing | fixed part to which the housing of the connector plug for balanced transmission is fixed.

Explanation of symbols

20 Server Device 21 Transceiver Module Mounting Base 22 Front Panel 23 Insertion Port 24 Motherboard 50, 50A, 50B Transceiver Module 51 Data Transmission / Reception Assembly 60 Printed Circuit Board 61 Card Edge Contact Portion 70 LSI
80, 80C Balanced transmission connector plug 81, 81C Plug housing 81b-81e Protruding part 81f Overhanging part 82 Ground terminal 83 Plug part 84 Shield member 90, 90C Module housing 91, 91C Upper housing half 92 Radiation fin 93, 94 Connecting part 95 Pedestal part 96 Flange half part 97, 97C Cover half part 98 Rib part 100, 101 Protruding part 102 Step part 103 Concave part for heat dissipation sheet 104 Convex part 105 Notch part 110, 110C Lower housing half 111 Flange half part 112, 112C Cover part 113 Rib portion 114, 115 Protruding portion 116, 117 Latch mechanism built-in portion 119 Flange portion 120 Screw 122, 122C Cover portion 140, 141 Gasket 150 Latch mechanism 151 Claw member 152 Locking surface 153 Surface 154 First cam portion 155, 156 Overhang portion 157 Coil spring accommodating groove portion 160 Coil spring 170 Pull sleeve 171 Pull sleeve body 172 Pull sleeve portion 173 Rod portion 174 Second cam portion 175 Protrusion part 176 Concave part 180 Lower metal plate member 181 Coil spring 185 Square frame 190, 191, 195 Groove part 192 Opening 193, 194 Stopper 200 Shield plate member 201 Body part 202 Mountain-shaped plate spring part 203 U-shaped plate spring part 250, 250Z1, 250Z2 Metal spring type gasket 260Y1, 260Y2 Cylindrical gasket 300Y1, 300Y2 Reverse trapezoidal groove 301Y1, 301Y2 Trapezoidal groove 310Y1, 310Y2 Reverse trapezoidal protrusion 320Y1, 320Y2 Trapezoidal protrusion

Claims (15)

A metal housing having a rectangular parallelepiped shape, one side on the front side on the longitudinal direction and the other side on the tip side in the insertion direction, a data transmitting / receiving unit provided inside the housing for transmitting and receiving data, A front-side external connection connector, a contact portion on the distal end side in the insertion direction of the housing, and a latch mechanism;
A transceiver module that is inserted into an information processing device with the contact portion at the top, is latched with respect to the information processing device by the latch mechanism, and is used by connecting the contact portion to an interface of the information processing device In
The latch mechanism is
A locking claw member provided in the housing so as to be slidable in the width direction so that a part protrudes from a side surface thereof, and having a first cam portion on the front side in the longitudinal direction ;
A spring member for protrusion that is located on the inner side in the width direction of the locking claw member and biases the locking claw member in a direction protruding from the side surface of the housing;
A pull sleeve that is provided on the front side of the housing so as to surround the external connection connector is provided integrally. When the pull sleeve is pulled, it acts on the first cam portion of the locking claw member. A second cam portion that pulls the locking claw member into the housing against the protruding spring member;
The transceiver module, wherein the locking claw member and the protruding spring member are separate parts. A semiconductor package having a function of transmitting and receiving data is mounted on a printed circuit board, a balanced transmission connector plug is mounted on one end side of the printed circuit board, and the other end side of the printed circuit board is a card edge contact portion. A data transmission / reception assembly is incorporated in a metal housing and has a latch mechanism;
Inserted into the information processing device with the card edge contact portion at the top, latched to the information processing device by the latch mechanism, and used by connecting the card edge contact portion to the interface of the information processing device Transceiver module
The latch mechanism is
A locking claw member provided in the housing so as to be slidable in the width direction so that a part protrudes from a side surface thereof, and having a first cam portion on the front side in the longitudinal direction ;
A spring member for protrusion that is located on the inner side in the width direction of the locking claw member and biases the locking claw member in a direction protruding from the side surface of the housing;
A pull sleeve provided integrally with the balanced transmission connector plug on the front side of the housing is provided so as to act on the first cam portion of the locking claw member when the pull sleeve is pulled. And a second cam portion that pulls the locking claw member into the housing against the protruding spring member,
The transceiver module, wherein the locking claw member and the protruding spring member are separate parts. The transceiver module according to claim 1 or claim 2,
The latch mechanism is
The locking claw member has a shape in which the first cam portion is disposed closer to the front side of the housing in the locking claw member,
A force that pulls the locking claw member generated by the second cam portion acting on the first cam portion into the housing acts on a position of the locking claw member closer to the front side of the housing. A transceiver module characterized in that it is configured as described above. The transceiver module according to claim 1 or claim 2,
The latch mechanism is
A transceiver module, further comprising a spring member for returning the pulled pull sleeve to its original position. The transceiver module according to claim 1 or claim 2,
The latch mechanism is
The locking claw members are arranged on both sides of the housing;
The transceiver module according to claim 1, wherein the pull sleeve has a second cam portion that acts on the locking claws on both sides. The transceiver module according to claim 1 or claim 2,
The transceiver module has a configuration in which the housing has a plurality of radiating fins and a connecting portion that connects adjacent radiating fins on both ends of each radiating fin on the upper surface. The transceiver module according to claim 1 or claim 2,
2. The transceiver module according to claim 1, wherein the pull sleeve includes an inverted U-shaped pull sleeve portion and a lower metal plate member that horizontally spans both ends of the pull sleeve portion. The transceiver module according to claim 2,
The housing is a combination of an upper housing half and a lower housing half,
A transceiver comprising a mechanism for regulating the position of the balanced transmission connector plug in the height direction and the lengthwise direction of the transceiver module inside the upper housing half and the lower housing half. module. The transceiver module according to claim 2,
The housing is a combination of an upper housing half and a lower housing half,
A metal sponge-like gasket is sandwiched between the upper surface of the balanced transmission connector plug and the upper housing half,
A transceiver module characterized in that a metal sponge-like gasket is sandwiched between the lower surface of the balanced transmission connector plug and the lower housing half. The transceiver module according to claim 2,
The housing is a combination of an upper housing half and a lower housing half,
A heat radiation sheet is sandwiched between the upper surface of the semiconductor package and the lower surface of the upper housing half,
The transceiver module is characterized in that a portion of the lower surface of the upper housing half facing the heat radiating sheet has a plurality of convex portions, and the plurality of convex portions press the heat radiating sheet. The transceiver module according to claim 1 or claim 2,
The latch mechanism is
A rod portion that is integral with the pull sleeve and has the second cam portion formed thereon;
The rod portion is configured to enter the housing through an opening formed in a flange portion at one end of the housing;
The rod portion has a shield plate member,
The shield plate member is oriented perpendicular to the axis of the rod portion, and has a size corresponding to the opening of the flange portion when viewed from the front side of the transceiver module, and is in contact with the housing. The transceiver module is configured to limit leakage of electromagnetic waves from the opening of the flange portion through which the rod portion passes. The transceiver module of claim 11, wherein
The shield plate member has a U-shaped spring portion,
When the U-shaped spring part is in contact with a part of the housing, and when the pull sleeve is pulled, it elastically deforms and stores spring force, and when the pull sleeve is released from the pull operation A transceiver module characterized in that the pull sleeve is returned to its original position by the stored spring force. The transceiver module of claim 11, wherein
The rod part has a slit part and a core part at the back of the slit part,
The shield plate member has a notch,
The transceiver module, wherein the shield plate member is press-fitted into the slit portion, and the cutout portion is fitted to the core portion. The transceiver module according to claim 1 or claim 2,
On the upper surface and the lower surface near the front side of the housing, a metal spring type gasket member having a shape in which a plurality of leaf spring portions inclined toward the front direction are arranged,
A transceiver module characterized in that each leaf spring part is in close contact with the edge of the opening of the information processing apparatus in a state where the transceiver module is inserted into the information processing apparatus through the opening of the information processing apparatus. The transceiver module according to claim 1 or claim 2,
Of the side surfaces of the housing, a columnar gasket is incorporated on the back side of the flange portion,
A transceiver module characterized in that the columnar gasket is in close contact with the edge of the opening of the information processing device in a state where the transceiver module is inserted into the information processing device through the opening of the information processing device.

Images