Optoelectrical transceiver module with releasing mechanism

A pluggable optoelectrical transceiver module (99) is adapted to be retained in a metal cage (5). The optoelectrical transceiver module comprises a receptacle (3), a housing (4) covering a front portion (10) of the receptacle, and a releasing mechanism (2). A triangular latch (11) extends from the receptacle and engages with a retaining tab of the cage. A driving device (2) of the releasing mechanism is rotatably attached to the front portion of the receptacle, and moves an ejector (21) forward and rearward. When the driving device is pulled forward, the ejector slides rearward in the receptacle, unlatching the triangular latch from the cage.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an optoelectrical transceiver module for optical communications, and in particular to an optoelectrical transceiver module pluggable into a metal cage and having a releasing mechanism.

2. Description of the Related Art

Optoelectrical transceiver modules provide bi-directional transmission of data between an electrical interface and an optical data link. The module receives electrically encoded data signals, which are converted into optical signals and transmitted over the optical data link. The module also receives optically encoded data signals, which are converted into electrical signals and transmitted onto the electrical interface.

The optoelectrical module is generally retained in a complementary cage. The cage conventionally comprises spring means located in a rear portion thereof. When the optoelectrical module is withdrawn from the cage, an ejecting block of the optoelectrical module forces a fixed latch of the optoelectrical module out from a retaining hole defined in a spring latch of the cage. The fixed latch is released from the spring latch. The optoelectrical module is then ejected from the cage by the spring means. The optoelectrical module forms a guide rail at a bottom of a front portion thereof. The ejecting block slidably engages in the guide rail at the bottom of the optoelectrical module. In order to withdraw the optoelectrical module from the cage, the ejecting block is manually pushed inwardly, under the optoelectrical module. However, it is inconvenient to manually push the ejecting block at that location. This is particularly so in modem systems having high port densities in and around the cage that restrict access to the ejecting block.

An improved optoelectrical transceiver module, which provides for convenient withdrawal of the module from a complementary cage is desired.

An example of an optoelectrical transceiver that uses a release mechanism is disclosed in co-pending application, U.S. Ser. No. 10/084,526, filed by the same inventor as this application. It is hereby incorporated by reference. Moreover, the copending application U.S. Ser. No. 10/080,001 filed Feb. Feb. 20, 2002 with the same assignee as the invention, discloses one approach regarding release mechanism used with the transceiver module.

SUMMARY OF THE INVENTION

Therefore, an object of the present invention is to provide an optoelectrical module having a release device which is readily operated.

Another object of the present invention is to provide an unlatching mechanism for easily operating the abovementioned release device.

In order to achieve the object set forth above, an optoelectrical transceiver module in accordance with a preferred embodiment of the present invention comprises a receptacle, a housing covering a front portion of the receptacle, and a releasing mechanism. A triangular latch extends from the receptacle and engages with a retaining tab of a cage. A driving device of the releasing mechanism is rotatably attached to a front portion of the receptacle, and moves an ejector forward and rearward. When the driving device is pulled forward, the ejector slides rearward in the receptacle, unlatching the triangular latch from the cage.

Other objects, advantages and novel features of the present invention will be drawn from the following detailed description of a preferred embodiment of the present invention with attached drawings, in which:

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIG. 1 , an optoelectrical transceiver module 99 in accordance with a preferred embodiment of the present invention comprises an optoelectrical assembly 1 and a releasing mechanism 2 . The optoelectrical assembly 1 comprises a receptacle 3 for receiving the optoelectronic devices (not shown) therein, and a housing 4 , which covers a rear portion of the receptacle 3 . The releasing mechanism 2 is movably attached to the receptacle 3 , and comprises an ejector 21 , a driving device 22 and a linking rod 23 .

Referring also to FIGS. 2 and 3 , the receptacle 3 is made of plastic material, end includes a front portion 10 , which is exposed forward of the housing 4 , and which is larger in cross-section than the rear portion of the receptacle 3 . A pair of guide rails 12 is formed in a bottom wall (not labeled) of the front portion 10 of the receptacle 3 . The guide rails 12 project inwardly toward each other. A triangular latch 11 is integrally formed on a bottom wall (not labeled) of the receptacle 3 , adjacent to the front portion 10 of the receptacle 3 . A pair of stamped pivot heads 13 respectively projects outwardly from opposite side walls (not labeled) of the front portion 10 of the receptacle 3 . A horizontal guide slot 14 is defined in each side wall (not labeled) of the front portion 10 , below the corresponding pivot head 13 .

The releasing mechanism 2 comprises the ejector 21 , the U-shaped driving device 22 and the linking rod 23 . The ejector 21 comprises a base 210 , with a pair of side walls 215 and a front wall (not labeled) extending upwardly from the base 210 . A pair of horizontal guide grooves 211 is defined in a front end of the side wall 215 of the ejector 21 . A pair of slanted ejecting protrusions 213 is formed at a rear end of the side walls 215 . A pair of co-axial through holes 212 is defined through the side walls 215 .

The driving device 22 comprises a top beam 221 , and a pair of latch arms 222 depending from opposite ends of the top beam 221 . A curved handle portion 223 extends upwardly from a front edge of the top beam 221 . A pair of pivot holes 224 is respectively defined in middle portions of the latch arms 222 . A pair of latch arm guide slots 225 is longitudinally defined below the pivot holes 224 and near free ends of the latch arms 222 , respectively.

The linking rod 23 comprises a round stop 232 at one end of the linking rod 23 . A washer 234 is mounted to an opposite end of the linking rod 23 , and a soldering ball 233 is soldered to the opposite end of the linking rod 23 .

In assembly, the ejector 21 is snapped onto the front portion 10 of the receptacle 3 with the guide grooves 211 slidingly accepting the guide rails 12 . The driving device 22 is attached to the front portion 10 of the receptacle 3 , with the stamped pivot heads 13 on the front portion 10 rotatably engaging within the pivot holes 224 of the driving device 22 . The linking rod 23 is inserted through one latch arm guide slot 225 of the driving device 22 , one horizontal guide slot 14 of the receptacle 3 , the through holes 212 of the ejector 21 , the second horizontal guide slot 14 , and the second latch arm guide slot 225 . The round stop 232 of the linking rod 23 is stopped at the guide slot 225 of the driving device 22 . The opposite end of the linking rod 23 protrudes from the second latch arm guide slot 225 . The washer 234 slides over the free end of the linking rod 23 and the soldering ball 233 is soldered to the free end of the linking rods 23 to rotatably secure the linking rod 23 to the driving device 22 . The driving device 22 is thus rotatably fastened on the front portion 10 of the receptacle 3 . Assembly of the releasing mechanism 2 on the optoelectrical assembly 1 is thus completed.

FIG. 4 schematically illustrates a process of releasing the optoelectrical module 99 from engagement inside a complementary cage 5 . The cage 5 has an inwardly protruding retaining tab 51 formed at a front part of a bottom plate thereof. The retaining tab 51 has a triangular hole 52 defined therein, and the triangular hole 52 engagingly retains the triangular latch 11 of the optoelectrical module 99 therein. To eject the optoelectrical module 99 from the cage 5 , the handle portion 223 of the driving device 22 is pulled forwardly away from the front of the optoelectrical module 99 . The driving device 22 thus pushes the ejector 21 rearward along the guide rails 12 . The ejecting protrusions 213 of the ejector 21 travel rearward and slide along an upper surface of the retaining tab 51 , pressing it downward and away from the optoelectrical module 99 . As a result, the retaining tab 51 is released from the triangular latch 11 , and the optoelectrical module 99 can be ejected from the cage 5 by conventional spring means (not shown) located in a rear portion of the cage 5 .

It should be understood that various changes and modifications to the presently preferred embodiment described herein will be apparent to those skilled in the art. Such changes and modifications may be made without departing from the spirit and scope of the present invention and without diminishing the present invention's advantages. Thus, it is intended that such changes and modifications be covered by the appended claims.