KR101208061B1 - Module for optical communication - Google Patents

Abstract

PURPOSE: An optical communications module is provided to specifically perform operations by rotating a latch and rotating a rotary lever with a trigger. CONSTITUTION: Electronic components are mounted inside a case(110) and a long recess is formed on the side of the case. The case hangs a tap of a case on an end of the long recess. A latch(120) is installed on the front side of the case which can be rotated back and forth and forms a trigger of a hook shape at one end. A rotary lever(130) is mounted on the long recess of the case and forms a bend portion which is pushed by the trigger according to rotation of the latch. The rotary lever rotates and let the opposite side of the bend portion push the tap toward outside.

Description

Optical communication module {Module for Optical Communication}

The present invention relates to an optical communication module, and more particularly, to an optical communication module configured to facilitate mounting and detachment from a cage by installing a lever using a lever principle in an XFP type standard optical communication module.

In general, an optical communication module is a device for converting a light signal into an electrical signal or an electrical signal into a light signal, and is mounted on an optical interface of a transmission repeater and a terminal through which an optical cable passes. For example, the speed of optical cables and optical communication modules, for example, 10Gb module is a speed that can send a full data in 8 seconds to 80GB memory hard disk.

The transmission repeater is configured to be equipped with a large number of optical communication modules, each of which is configured to be connected to the optical cable. Therefore, the optical communication module is often replaced by a factor such as troubleshooting, parts replacement, or upgrade. However, since such an optical communication module is equipped with a huge number of repeaters, it is very costly and time-consuming to replace all of them in order to replace them. Therefore, like other electronic components, optical communication modules and cages are standardized for quick replacement and cost reduction. XFP (10 Gigabit Small Form Factor Pluggable) type of optical communication module standard has a mechanical feature configured to be detachable from the cage by rotating and returning the rotary lever in front of it.

The cage into which the XFP type optical communication module is fitted is shown in FIGS. 1 and 3. The cage 20 is fixed to the optical interface of the repeater and the terminal, and the connector 32 is positioned at the rear lower portion of the cage 20 so that the optical communication module 10 is inserted into the cage 20 to be mounted therein, and thus the optical communication module ( 10) and the connector 32 is configured to be electrically connected. In addition, it has a configuration that does not fall out when the module 10 is fitted into the cage 20 mechanically. That is, a portion of both sides of the cage 20 forms a tab 21, and the tab 21 forms a state in which the tab 21 is bent slightly elastically into the cage 20. ) Is pushed outward when the tab 21 is pushed out, but when it is completely inserted and mounted, the tab 21 is pushed back inward to be caught by a part of the module 10 so that the module 10 does not normally fall out. Has Therefore, the tab 10 must be able to push outward and maintain the state so that the module 10 can be removed from the cage 20. As a result, the module 10 requires a mechanical design that pushes the tab 21 when detached and a portion caught by the tab 21 when mounted.

One example of the prior art is shown in FIGS. As shown, the module 10 is assembled into the cage 20 fixedly installed behind the EMI gasket 31 of the board 35 through the bezel 30. A heat sink 33 is installed on the upper part of the cage 20, and a clip 34 is assembled on the upper part of the cage 20. 2, a side view of the module 10 and cage 20 is shown. The upper part is the module 10 and the lower part is the cage 20. The module 10 is inserted into the cage 20 inlet from the rear to the end, and the tab 21 formed on the cage 20 in the jaw 14 of the groove in which the slider 12 on the side of the module 10 is fitted When caught, it is prevented from coming out. 2 and 3, a groove is formed on the side of the module 10 so that the slider 12 can linearly reciprocate horizontally and in parallel, and the slider 12 is mounted in the groove. The slider 12 has a projection 13 which protrudes slightly inwardly so that the tab 21 end of the cage 20 can be caught by the jaw 14 of the groove and then again protrudes along a linear curve. The protrusion 13 has the same thickness as the original slider 12. The slider 12 is also mechanically designed to move to the left as the latch 11 rotates counterclockwise in the figure. Of course, if the rotation is reversed, move to the right. Referring to FIG. 3, when the module 10 is inserted into the cage 20, the protrusion 13 of the module 10 pushes in while pushing the tab 21 of the cage 20 and enters the end of the cage 20. The tab 21 is retracted inward so that its end is caught by the jaw 14 of the module 10. Therefore, just pulling the module 10 is not separated. When the latch 11 is rotated in this state, the slider 12 comes out, and the protrusion 13 of the slider 12 pushes the tab 21 outward so that the module 10 can be detached from the cage 20. It becomes a state.

However, since the assembly structure of the optical communication module 10 according to the related art is a structure in which the latch 11 and the linear slider 12 are rotated, the structure is complicated and is assembled by assembling using rivets, pins, bolts, and the like. This is difficult and therefore there is a problem that the productivity is low because of the high number of production.

The present invention is to solve the problems as described above, the object of the structure is simple and easy to manufacture by completing the mechanical design of the module to be fitted to the XFP type cage by using the structure of the simple latch and lever structure And to provide an optical communication module that can achieve cost savings.

As a specific means for achieving the above object, the present invention is an electronic component for converting a light signal into an electrical signal or vice versa, and is detachably mounted in a cage fixed to an optical communication repeater or a terminal and bent inward with a portion of both sides of the cage. An optical communication module configured to be mounted by engaging a tab, comprising: a case in which electronic components are mounted therein, a long groove is formed at a side thereof, and a tab of the cage is caught at an end of the groove; A latch rotatably installed back and forth in front of the case and having a trigger formed at an end thereof; And a rotating lever mounted in the groove of the case and being bent by the trigger as the latch is rotated so that the opposite side of the bent portion pushes the tab outward.

Preferably, the upper and lower parts of the rotary lever is formed with a rotating shaft and the rotating shaft is assembled by rotatably fitted in the hole formed in the case.

Preferably, the latch is fitted to the rotating shaft formed on both sides of the case and then bent to form a handle portion, the trigger is formed on the opposite side of the handle around the rotating shaft.

Preferably, the trigger is formed in a hook shape.

Preferably, a stopper is formed on the groove of the case so that the end of the rotary lever is prevented from being rotated longer than a predetermined length.

The present invention as described above has the following effects.

(1) Since the latch is rotated so that the trigger of the latch rotates the rotary lever, the lever principle is used to provide the effect that the operation is surely and clearly.

(2) Since the structure consists of only the latch and the rotating lever, the structure is simple and it is easy to assemble by not assembling using rivets, pins, bolts, etc., thus providing the effect of improving productivity due to low production labor.

1 is a perspective view showing a coupling structure of an optical communication module according to the prior art.
Figure 2 is a side view for showing a coupling structure of the optical communication module according to the prior art.
3 is a cross-sectional view taken along line AA of FIG. 2.
4 is a perspective view of an optical communication module according to the present invention.
5 is a perspective view of the optical communication module according to the present invention showing a state in which the latch is operated by rotating.
6 is an exploded perspective view of the optical communication module according to the present invention.
7 is a perspective view of a portion of the optical communication module according to the present invention cut away, showing the state before and after the operation.
Figure 8 is a partially cut perspective view of the optical communication module according to the present invention, showing a state in which the rotating lever is a part component.
9 and 10 are cross-sectional views showing the operation of the optical communication module according to the present invention in combination with a cage. FIG. 9 shows before the operation and FIG. 10 shows the operation after the operation.

The objects, features and advantages of the present invention described above will become more apparent from the following detailed description. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

An optical communication module according to a preferred embodiment of the present invention is shown in FIG. As shown in the figure, the optical communication module 100 is formed of a long rectangular parallelepiped case 110, and various electronic components are installed in the case 110. The latch 110 is installed in the front of the case 110 so as to be rotatable back and forth, and the rotating lever 130 is installed at the side to be carried in and out like a wing. The rotary lever 130 is installed in the case 110 side groove 111a and is mechanically designed so that the end of the tab 21 of the cage 20 is not caught out by the end of the groove 111a.

Referring to FIGS. 4 and 5, FIG. 4 is a state in which the latch 120 stands vertically. When the latch 120 is pushed into the gauge 20, the tab 21 of the cage 20 is provided with the rotary lever 130. It is caught by the end of the groove 111a so that mounting is completed and does not come out. 5 shows a state in which the latch 120 is rotated 90 degrees forward. At this time, the rotary lever 130 is rotated so that the rear of the spring to the outside to push the tab 21 of the gauge 20 is in a state that can eventually separate the module 100 from the gauge 20.

6 is an exploded perspective view of the optical communication module 100 according to the present invention, the configuration of which is shown in detail. The optical communication module 100 according to the present invention is an electronic component that converts a light signal into an electrical signal or vice versa. The optical communication module 100 is mounted on and detached from a cage 20 fixed to an optical communication repeater or a terminal. The optical communication module 100 is configured to be mounted by engaging the tab 21 bent by the. The module 100 includes a case 110 in which electronic components are mounted therein, an elongated groove 111a is formed at a side thereof, and a tab 21 of the cage 20 is caught at an end of the groove 111a. As the latch 120 is rotatably installed in front of the case 110 and is mounted to the latch 120 having the trigger 120b formed at the end and the groove 111a of the case 110, and the latch 120 rotates. The bent portion 130a pressed by the trigger 120b is formed, and the opposite side of the bent portion 130a is composed of a rotary lever 130 which is rotated to press the tab 21 outward. Rotating shafts 130b are formed at upper and lower portions of the rotating lever 130, and the rotating shafts 130b are rotatably fitted into holes 111b formed in the case 110. The case 110 includes a main body 111 having an open top shape and a cover 112 assembled to the top. In front of the cover 112, a head cover 113 is added. Therefore, the upper rotary shaft 130b of the rotary lever 130 is assembled into a groove (not shown) formed in the cover 112, and the lower rotary shaft 130b is fitted into the hole 111b formed in the case body 111, respectively. The latch 120 is fitted to the rotating shaft (111c) formed on both sides of the case 110, and then bent to form the handle portion (120a), the opposite to the handle portion (120a) around the rotation shaft (111c) Trigger 120b is formed. The trigger 120b is formed in a hook shape. The latch 120 has a trigger 120b on one side and a handle 120a on one side about the rotation shaft 111c. The trigger 120b is pressed while being rotated while contacting the bent portion 130a of the rotary lever 130. A stopper 130c is formed on the inner wall of the case 110 so that the end of the rotary lever 130 is prevented from rotating over a predetermined length. Therefore, the rotation lever 130 may not be rotated more than a certain angle.

The case 110 is assembled with a plurality of parts in the lower body 111, the cover 112 is placed on the top. The head cover 113 is added to the front of the cover 112, the head cover 113 not only protects the latch 120, but also covers the rotary shaft 111c of the latch 120 to assemble the latch 120. It protects the state and prevents it from being separated. The latch 120 may be opened slightly to assemble the rotary shaft 111c into the hole 120c and to cover the head cover 113. A groove 111a on which the rotary lever 130 is mounted is formed on the side of the main body 111, and the rotary lever 130 is mounted on the groove 111a. A hole 111b is formed in the lower portion of the groove 111a to fit the lower rotation shaft 130b of the rotation lever 130. A cutout 111d is formed at the end of the groove 111a so that the stopper 130c of the rotary lever 130 can be passed and assembled, and the stopper 130c is caught by the inner wall to rotate the lever 130. Limit the rotation angle.

The rotary lever 130 is usually made of a long thin metal, the upper and lower parts of the rotating shaft 130b is formed, the rear end of the stopper (130c) is bent by the trigger 120b in the front bent portion (130a) Is formed. When the trigger 120b is rotated to press the bent portion 130a, the bent portion 130a is pressed to rotate the rotation lever 130 about the rotation axis 130b.

Referring to FIG. 7, a part of the case 110 is cut in a state in which the latch 120 and the rotation lever 130 are well seen, and the upper part of the latch 120 is operated. The rotary lever 130 is also located in the original home position because it is located in its original position, and the state of the lower part is the state in which the latch 120 is rotated and positioned in the operating position. The rotated state is shown.

In the original position of the upper latch 120 is vertically erected so that the handle portion 120a is located in the upper position, the rotary lever 130 is in a state lying in parallel with the case (110). Therefore, at this time, the trigger 120b of the latch 120 does not press the bent portion 130a of the rotary lever 130. In the lower operating state, the handle portion 120a of the latch 120 is placed at the front, and the latch 120 is rotated forward, and the rotation lever 130 is rotated about the rotation shaft 130b to rotate the rotation lever 130. ) The other end of the bent portion 130a protrudes outward. Therefore, at this time, the trigger 120b of the latch 120 is in a state of pressing the bent portion 130a of the rotary lever 130. Of course, at this time, the stopper 130c is hung inside the case 110.

Referring to FIG. 8, the case body 111 in a state where the latch 120 and the rotation lever 130 are removed is shown. As shown, the groove 111a of the main body 111 is formed with a hole 111b into which the rotating shaft 111b is fitted, and the groove 111a is further inclined inward with respect to the hole 111b. Formed. This can also be seen in FIGS. 9 and 10. By forming the inclined in this way provides a space in which the rotary lever 130 can be rotated.

9 and 10, the mounting and detachment of the gauge 20 and the module 100 is well illustrated. FIG. 9 is a cross-sectional view of the case 110 and is a home position in which the latch 120 is not rotated in the state of FIG. 9, and the tab 21 of the gauge 20 is pushed in by the elastic force to the case body 111. The groove 111a is in the state of being hung and the rotary lever 130 is also in its original position. 10 is a cross-sectional view of the case body 111 from above, in the state of FIG. 10, the latch 120 is rotated so that the trigger 120b presses the bent portion 130a of the rotation lever 130 to rotate the rotation lever 130. Rotating and the end of the rotary lever 130 pushes the tab 21 of the cage 20 to the outside shows the state of the operating position that the module 100 can be separated from the cage 20. Pulling the latch 120 in the same state as in FIG. 10 separates the module 100 from the cage 20.

Although the trigger is configured to press the bent portion in the present embodiment, the lever may be rotated by being pressed by the trigger in various other ways, such as forming a protrusion at the end of the lever to be pressed by the trigger instead of the bent portion. to be.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

20: cage 21: tab
100: optical communication module 110: case
120: latch 130: rotation lever

Claims (5)

An electronic component for converting a light signal into an electrical signal or vice versa, an optical communication module configured to be mounted on a cage fixed to an optical communication repeater or a terminal, and mounted on a tab bent inwardly with a portion of both sides of the cage,
A case in which electronic components are mounted therein, a long groove is formed at a side thereof, and a tab of the cage is caught at an end of the groove;
A latch rotatably installed forward and backward in front of the case and having a hook-shaped trigger formed at an end thereof;
A rotating lever mounted in a groove of the case and formed to be bent by the trigger as the latch is rotated so that the opposite side of the bent portion pushes the tab outward;
Including,
The latch is fitted to the rotary shaft formed on both sides of the case and extended and then bent to form a handle portion, the trigger is formed on the opposite side of the handle around the rotary shaft, the case of the rotary lever to prevent rotation over a predetermined length Optical communication module formed with a stopper that is caught in the groove of the. The method of claim 1,
The upper and lower parts of the rotary lever is formed with a rotating shaft and the rotating shaft is assembled to be rotatably inserted into a hole formed in the case. delete delete delete

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