JP2010175575A - Optical connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical connector, eliminating signal noise even while narrowing a pitch between a light emitting device and a photodetector. <P>SOLUTION: A FOT (fiber optic transceiver) 2a at transmission end and a FOT 2b at the receiving end are covered with a first shield case 4, and a combination contact and pressing part 14 of a second shield case 5 is caused to come into contact with the rear side of the first shield case 4 by mounting the second shield case 5, so that signal noise generated between the FOT 2a at transmission end and the FOT 2b at the receiving end is released to the ground through the combination contact and pressing part 14 of the second shield case 5 and a ground part 16. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical connector including a transmission-side FOT (Fiber Optic Transceiver) and a reception-side FOT.

  For example, a conventional optical connector disclosed in Patent Document 1 below is a state in which a transmission-side FOT having a light-emitting element, a reception-side FOT having a light-receiving element, the transmission-side FOT, and the reception-side FOT are arranged side by side. An optical connector housing having FOT accommodation chambers that are accommodated at predetermined intervals, and a shield case that covers the optical connector housing and covers the transmission-side FOT and the reception-side FOT that are accommodated in the FOT accommodation chamber. Has been.

  The shield case has a pair of convex portions. The pair of convex portions are formed on the walls facing the back surfaces of the transmission-side FOT and the reception-side FOT. On the other hand, the optical connector housing has a FOT partition in the FOT accommodation chamber. The FOT partition wall is formed as a crosstalk prevention wall protruding across between the transmission side FOT and the reception side FOT. The FOT partition is formed in such a shape that the tip is inserted between a pair of convex portions of the shield case in a state where the shield case is assembled to the optical connector housing.

  In the configuration and structure described above, if an optical signal leaks from the transmission-side FOT, the optical signal (signal noise) leaked in the lateral direction is blocked by the FOT partition. Further, the optical signal (signal noise) leaked rearward is blocked by the convex portion and the tip of the FOT partition wall.

JP 2006-215273 A

  In order to reduce the size of the optical connector, it is conceivable to reduce the pitch between the light emitting element and the light receiving element. However, narrowing the pitch between the light emitting element and the light receiving element narrows the distance between the FOT on the transmission side and the FOT on the reception side, and thus provides a convex part of the shield case and an FOT partition wall in the FOT storage chamber. As a result, there is a problem that the signal noise cannot be blocked by the FOT partition and the signal noise cannot be blocked by the convex portion and the tip of the FOT partition. Since signal noise affects, for example, light reception of the FOT on the receiving side, it can be said that it is necessary to take effective measures for removing signal noise.

  The present invention has been made in view of the above circumstances, and provides an optical connector capable of effectively removing signal noise even when the pitch between a light emitting element and a light receiving element is narrowed. Is an issue.

  In order to solve the above-mentioned problems, an optical connector of the present invention according to claim 1 includes a transmission-side FOT (Fiber Optic Transceiver), a reception-side FOT, the transmission-side FOT, and the reception-side FOT. A metal first shield case that covers these in a state where they are arranged and in close proximity, and a metal second shield case having a contact portion that contacts the first shield case and a ground portion that functions as a ground. It is a feature.

  According to the present invention having such characteristics, signal noise generated between the transmission-side FOT and the reception-side FOT is released from the first shield case to the ground through the ground portion of the second shield case. According to the present invention, the signal noise from the FOT on the transmission side does not affect the light reception of the FOT on the reception side. It can be said that the present invention is a measure for effectively removing signal noise in order to realize miniaturization of the optical connector.

  An optical connector according to a second aspect of the present invention is the optical connector according to the first aspect, wherein the contact portion passes the FOT on the transmitting side and the FOT on the receiving side through the first shield case in the optical axis direction. It is also characterized by the fact that it is also an elastic pressing part that presses against.

  According to the present invention having such a feature, the FOT on the transmission side and the FOT on the reception side are pressed in the optical axis direction by the contact portion / pressing portion. If there is a gap between the FOT and, for example, an optical fiber, this gap can be reduced (light loss can be minimized).

  According to the first aspect of the present invention, there is an effect that signal noise can be effectively removed even when the pitch between the light emitting element and the light receiving element is narrowed.

  According to the second aspect of the present invention, there is an effect that a better example of the contact portion can be proposed.

It is a figure which shows one Embodiment of the optical connector of this invention, (a) is a disassembled perspective view of an optical connector, (b) is sectional drawing of an optical connector. It is a disassembled perspective view of an optical connector. It is a perspective view of FOT. It is a figure which shows the state of FOT and a 1st shield case by making the rear part of a 2nd shield case into a cross section. FIG. 5 is a view (a state without a first shield case) as a comparative example of FIG.

  Hereinafter, description will be given with reference to the drawings. 1A and 1B are diagrams showing an optical connector according to an embodiment of the present invention. FIG. 1A is an exploded perspective view of the optical connector, and FIG. 2 is an exploded perspective view of the optical connector, FIG. 3 is a perspective view of the FOT, FIG. 4 is a view showing the state of the FOT and the first shield case with the rear part of the second shield case taken as a cross section, and FIG. It is a figure (state without a 1st shield case) used as a comparative example.

  In FIG. 1, reference numeral 1 indicates an optical connector of the present invention. The optical connector 1 is of a receptacle type mounted on a circuit board (not shown), and includes an FOT (Fiber Optic Transceiver) 2, an optical connector housing 3, a first shield case 4, and a second shield case 5. It is prepared for. First, each component will be described (an arrow P in FIG. 1 is defined as a front-rear direction, an arrow Q as an up-down direction, and an arrow R as a left-right direction).

  1 to 3, the FOT 2 includes an FOT main body 6 having optical elements and a plurality of substrate connecting pins extending from the FOT main body 6, that is, lead frames 7. Two FOTs are provided, one on the transmission side (light emission side) and the other on the reception side (light reception side) (the FOT on the transmission side is 2a, and the FOT on the reception side is 2b). The transmission-side FOT 2a has a light-emitting element, and the reception-side FOT 2b has a light-receiving element. Each optical element is connected to the corresponding lead frame 7 by wire bonding or the like.

  The rear surface of the FOT main body 6 is formed flat. This rear surface is pressed forward by the second shield case 5 with the first shield case 4 interposed. On the front surface of the FOT main body 6, an annular guide portion 8 serving as a connection partner guide portion at the time of optical connection is formed.

  The lead frame 7 has a quadrangular cross section and is not particularly limited. The lead frame 7 extends downward from the lower portion of the FOT main body 6 and is substantially continuous in the forward or rearward direction following the first portion 7a. It has a second portion 7b that extends and a third portion 7c that continues to the second portion 7b and extends downward. The tip of the third portion 7c is inserted into a circuit board (not shown) and soldered to the corresponding circuit. The lead frames 7 are arranged in a staggered manner as shown in the figure.

  1 and 2, the optical connector housing 3 is a member made of synthetic resin having insulation properties, and has a FOT accommodating chamber 9 formed by opening the rear surface of the housing. The FOT accommodation chamber 9 is formed so as to accommodate two FOTs 2 covered by the first shield case 4.

  The optical connector housing 3 has locking recesses 10 for fitting and locking the first shield case 4 on the respective walls on the left and right sides of the FOT housing chamber 9. The optical connector housing 3 has a locking recess 11 for fitting and locking the second shield case 5 in front of the locking recess 10.

  The first shield case 4 is formed by pressing a thin metal plate having conductivity. The first shield case 4 is provided for noise countermeasures. The first shield case 4 is formed in a substantially cylindrical shape so as to cover the periphery of the FOT main body 6 in a state where the FOT 2a on the transmission side and the FOT 2b on the reception side are arranged and close to each other. The first shield case 4 having such a shape has a partition plate 12 made of the thin metal plate. The partition plate 12 is disposed and formed so as to be interposed between the transmission-side FOT 2a and the reception-side FOT 2b.

  On both the left and right sides of the first shield case 4, elastic locking pieces 13 that are hooked and locked in the locking recesses 10 of the optical connector housing 3 are formed. The locking piece 13 is formed in a leaf spring shape. On the front side of the first shield case 4, through holes (reference numerals omitted) for the annular guide portions 8 of the transmission-side FOT 2 a and the reception-side FOT 2 b are formed. On the other hand, a flat surface is formed on the rear side of the first shield case 4. The rear side of the first shield case 4 is a surface that receives pressure from the second shield case 5.

  Similar to the first shield case 4, the second shield case 5 is formed by pressing a thin metal plate having conductivity. The second shield case 5 is also provided for noise countermeasures. In this embodiment, the second shield case 5 is formed in a box shape that covers the optical connector housing 3 (assumed to be an example).

  The second shield case 5 has a contact portion / pressing portion 14 (contact portion, pressing portion) that contacts the rear side of the first shield case 4. The contact portion / pressing portion 14 has a leaf spring shape and an indent, and has a function of electrically contacting the first shield case 4, a transmission-side FOT 2 a and a reception side via the first shield case 4. The FOT 2b is pressed in the optical axis direction.

  Reference numeral 15 in the second shield case 5 indicates a fixing portion for being inserted into and fixed to a circuit board (not shown). Reference numeral 16 indicates a ground portion. The ground portion 16 is soldered to the ground of a circuit board (not shown). Reference numeral 17 denotes a locking piece that is hooked and locked in the locking recess 11 of the optical connector housing 3.

  Next, assembly of the optical connector 1 of the present invention will be described based on the above configuration and structure.

  As shown in FIGS. 1A and 2, the FOT bodies 6 of the transmission-side FOT 2 a and the reception-side FOT 2 b are covered with a first shield case 4, and thereafter, as shown in FIG. The transmission-side FOT 2a and the reception-side FOT 2b covered with the first shield case 4 are accommodated in the FOT accommodation chamber 10 (the FOT main body 6) by press fitting. The accommodation at this time is such that the optical connector housing 3 is moved from the rear to the front. After accommodating the transmitting-side FOT 2a and the receiving-side FOT 2b covered by the first shield case 4, the second shield case 5 is assembled (attached) so as to cover the optical connector housing 3, and a series of assembly is performed. Complete.

  In the optical connector 1 of the present invention, the FOT 2a on the transmission side and the FOT 2b on the reception side are covered with the first shield case 4, and the second shield case 5 is contacted by the attachment of the second shield case 5. Since the part / pressing part 14 contacts the rear side of the first shield case 4, signal noise generated between the transmission-side FOT 2 a and the reception-side FOT 2 b is caused by the contact part / pressing part 14 of the second shield case 5. And it is escaped to the ground via the ground part 16. Therefore, the signal noise from the FOT 2a on the transmission side does not affect the light reception of the FOT 2b on the reception side (the first shield case 4 does not exist and the conventional type optical connector as shown in FIG. 5). In the case of 101, if the interval between the transmission-side FOT 2a and the reception-side FOT 2b is narrowed, signal noise occurs in the direction of the arrow, that is, crosstalk occurs. The optical connector 1 of the present invention can effectively remove signal noise (although not particularly shown, a waveform indicating that the signal noise of the transmission-side FOT 2a is not leaked to the reception-side FOT 2b is obtained). .

  As described above with reference to FIGS. 1 to 5, according to the present invention, the pitch between the light emitting element and the light receiving element is narrowed, in other words, the distance between the FOT 2a on the transmitting side and the FOT 2b on the receiving side. Even in a narrowed state, the signal noise can be effectively removed. This also brings about an effect that the optical connector can be miniaturized.

  Since the signal noise generated between the FOT 2a on the transmission side and the FOT 2b on the reception side is released to the ground via the contact portion / pressing portion 14 and the ground portion 16 of the second shield case 5, the first shield case 4 There is no need to provide a ground portion, and even with the configuration of the present invention, an increase in the number of pins can be suppressed.

  It goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

  The present invention can also be applied to a hybrid connector having the functions of both an optical connector and an electrical connector, and a pigtail type optical connector.

1 Optical connector 2 FOT
2a Sending FOT
2b FOT on the receiving side
3 Optical Connector Housing 4 First Shield Case 5 Second Shield Case 6 FOT Main Body 7 Lead Frame 7a First Part 7b Second Part 7c Third Part 8 Annular Guide 9 FOT Storage Chamber 10, 11 Locking Recess 12 Partition plate 13 Locking piece 14 Contact part and pressing part (contact part, pressing part)
15 Fixing part 16 Ground part 17 Locking piece

Claims (2)

A transmission-side FOT (Fiber Optic Transceiver); a reception-side FOT; a first shield case made of metal that covers the transmission-side FOT and the reception-side FOT in a state where they are arranged and close to each other; An optical connector comprising: a metal second shield case having a contact portion that contacts the shield case and a ground portion that functions as a ground. The optical connector according to claim 1,
The optical connector, wherein the contact portion is also an elastic pressing portion that presses the transmission-side FOT and the reception-side FOT in the optical axis direction through the first shield case.

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