DE102006005070A1 - Optical connector for use in the field of optical communication has a pair of convex sections on the wall of shielding housing, arranged opposite to the rear surface of light transmitting and light receiving-fiber optic transceiver - Google Patents

Abstract

Optical connector (1) has a pair of convex sections (53) on the wall (50) of shielding housing (7), arranged opposite to the rear surface of light transmitting-fiber optic transceiver (FOT) (5) and light receiving-FOT (6). The FOT-receiving section (22,23) has FOT-partition wall (28), preventing cross-talk, which protrudes over the area, which extends between light emitting-FOT and light receiving-FOT. The shielding housing is attached to the connector housing (2) so that it uncovers light emitting-FOT and Light receiving-FOT, and a distal end (29) of the FOT-partition wall is implemented into the gap between both convex sections, and held in this gap.

Description

The The present invention relates to an optical connector based on is used in the field of optical communication, and concerns more specifically, an optical connector having a shield case, a measure against electromagnetic noise.

An optical connector comprises a plug-type optical connector, and a jack-type optical connector in which the plug-type optical connector is fitted. A ferrule provided at an end portion of an optical fiber is received and held in the plug-type optical connector. On the other hand, the jack-type optical connector is adapted to be mounted on a printed circuit board provided in a device. More specifically, the female type optical connector has an optical connector housing having mounting portions for mounting to the printed circuit board, a light emitting fiber FOT (optical fiber transceiver) having a light emitting element, a light receiving FOT including a light receiving element and a shield case covering the light-emitting FOT and the light-receiving FOT together to provide an electrical noise shielding measure (see, for example, JP-A-2004-126015 (page 3); 17 to 20 )). Both the light-emitter FOT and the light-receiving FOT have a plurality of lead frames by which each is connected to the circuit board. The light emitter FOT and the light receiving FOT are arranged side by side. The shield case is formed so as to press a shiny, thin metal sheet which has not been subjected to any special surface treatment.

at the above-described, conventional approach the light emitter FOT and the light receiving FOT adjacent to each other arranged, with a predetermined gap between them is, and is a wall of the shielding housing opposite rear surfaces of the Light emitter FOT and the light receiving FOT is arranged, behind arranged this gap, so that there was a fear that optical Signals emerging from the light emitter FOT as noise in enter the light receiving FOT, either directly or after reflection through this wall of the shielding housing, whereby "crosstalk" is generated.

The the present invention has been developed in the light of the foregoing circumstances, and an advantage of the invention is the provision of a optical connector, which can prevent the occurrence of crosstalk.

The The above problem has been addressed by an optical connector according to the invention solved, having a light emitter FOT (optical fiber transceiver), having a light emitting element, a light receiving FOT, the a light receiving element, a connector housing, the a FOT receiving section in which the light emitter FOT and the light receiving FOT are received adjacent to each other, and a shielding housing, which together the light emitter FOT and the light receiving FOT covering, to a countermeasure against electromagnetic noise in this regard put; and which is characterized in that a pair convex Sections is provided on the wall of the shield case, the opposite rear surfaces of the Light emitter FOT and the light receiving FOT is arranged; in which the PHOT recording section has a FOT partition to prevent crosstalk that has over an area between the light-emitting FOT and the light-receiving FOT projecting; wherein when the shield case is mounted on the connector housing is to cover the light-emitting FOT and the light-receiving FOT distal end of the FOT partition into a gap between the two convex sections introduced is, and is held in the gap.

at the invention with the features described above, if an optical signal could leak out of the light emitter FOT, in Transverse outgoing optical signal through the FOT bulkhead shut off. Furthermore, the backward outgoing optical signal through the convex sections and the distal end of the FOT bulkhead blocked.

The distal end of the FOT partition may be arranged to be not in contact with the wall and the convex sections.

In the invention having the above-mentioned features, when the shield case is to be attached to the connector housing, the shield case is not pressurized by the distal end of the FOT partition wall, so that deformation does not occur. Therefore, grounding pins provided on the shielding case are not displaced relative to their location, and can be properly handled with a lever terplatte be connected.

Everyone the convex portions may be a substantially semi-cylindrical one Have shape.

at the invention having the above-described features each convex section on a semi-circular shape, leaving an optical Signal is scattered by the convex portion. This leads to, that the optical signal is less likely to be in a gap between penetrate the distal end of the FOT bulkhead and the shield case can. When the optical signal enters this gap, will spread around the distal end of the FOT bulkhead the optical signal again through the other, convex portion scattered (since the two convex portions are provided), whereby the occurrence of a crosstalk is prevented.

The shield has a housing shielding section which covers a connector fixing portion of the connector housing, and the connector fixing portion has a groove into which an end portion of the housing shielding portion introduced becomes.

at the invention with the above features is the countermeasure against electromagnetic noise also for the connector mounting portion intended. The housing shielding section for shielding the connector housing is at its end portion in the groove in the connector attachment portion introduced, and therefore, the end portion of the housing shielding portion does not expand from, thereby preventing a large gap between the end portion and the connector attachment portion. This leads to, that the effect of shielding the connector mounting portion is maintained.

at The invention achieves the advantage that the occurrence of crosstalk is prevented. Furthermore, the advantage is achieved that the arrangement provided inexpensively for preventing the occurrence of crosstalk can be.

at The invention achieves the advantage that the deformation of the shield is prevented. Therefore, the advantage is achieved that the ability the shielding housing, can be attached to a circuit board is not reduced.

at Invention achieves the advantage that an optical signal scattered can be prevented, thereby preventing the optical signal in penetrates the gap between the distal end of the FOT bulkhead and the shield case. Therefore, the advantage is achieved that prevents the occurrence of crosstalk becomes.

at The invention achieves the advantage that the connector attachment portion can be shielded. Furthermore, the advantage is achieved that it is prevented that the end portion of the Gehäuseabschirmabschnitts section widened, whereby the effect of shielding the connector mounting portion is maintained.

The The invention will be described below with reference to drawings explained in more detail, from which further benefits and features emerge. It shows:

1 a cross-sectional view of a preferred embodiment of an optical connector according to the present invention;

2 an exploded perspective view of the optical connector;

3 Fig. 11 is a view showing a state in which a light-emitting FOT and a light-receiving FOT are mounted in a FOT photographing section;

4 a perspective view of the optical connector;

5 a plan view of a connector housing;

6 a side view of the connector housing;

7 a front view of the connector housing;

8th a view from the rear of the connector housing;

9 a front view of a shielding housing;

10 a view from the rear of the shield case;

11 a side view of the shielding; and

12 a view from below of the shielding.

1 Fig. 12 is a cross-sectional view of a preferred embodiment of an optical connector according to the invention. 2 is an exploded perspective view of the optical Ver binders, 3 Fig. 15 is a view showing a state in which a light-emitting FOT and a light-receiving FOT are mounted in a FOT accommodating section, 4 is a perspective view of the optical connector, the 5 to 8th FIG. 4 is a plan view, a side view, and a front view and a rear view, respectively, of a connector housing, and FIG 9 to 12 are a front view, a rear view, a side view and a bottom view of a shield case.

In the 1 and 2 denotes the reference numeral 1 An optical connector according to the invention used in optical communication for an OA system, an FA system, an on-vehicle device, and the like. The optical connector 1 according to the invention is of the type of a socket, and has the connector housing 2 on, a pair of thimbles 3 , a pair of light guide parts 4 , the light emitter FOT (fiber optic transceiver) 5 up, the light-receiving FOT 6 , and the shield case 7 , The components will be described below with reference to FIGS 1 to 12 described.

The connector housing 2 is formed substantially box-shaped, using an insulating resin, and this connector housing 2 has a connector attachment portion 8th and the FOT recording section 9 on. The connector attachment portion 8th is formed so that a plug-type optical connector (not shown) can be mounted there. The connector attachment portion 8th is at a front side portion of the connector housing 2 intended. The connector attachment portion 8th has a mounting space 10 on, which is provided in it, and is open to the front of the connector housing. The optical connector (not shown) of the plug type can be placed in this mounting space 10 be introduced. A groove 11 is in that portion of the connector mounting portion 8th provided in the vicinity of the open portion of the connector attachment portion 8th is available. The groove 11 is on a sidewall 12 of the connector housing 2 provided, and an end portion (a below-described insertion end portion 47 ) of the shield case 7 is designed to be in the groove 11 to be introduced.

A partition 13 is between the connector mounting portion 8th and the FOT recording section 9 intended. A pair of stepped through holes 14 extends through the partition 13 , The pair of stepped through holes 14 is disposed so that each of these holes corresponds to a pair of ferrules (not shown) mounted in the plug-type optical connector (not shown), respectively. Each graduated passage laugh 14 has a smaller diameter portion that is close to the connector mounting portion 8th is arranged, and a larger diameter portion, which is in the vicinity of the FOT receiving portion 9 is arranged. The stepped through hole 14 further includes a middle diameter portion located between the smaller diameter portion and the larger diameter portion. Several press-fit projections 15 are on an inner surface of the smaller-diameter portion of the stepped through-hole 14 provided, and arranged at regular intervals.

slots 16 and 17 are in the outer surface of that portion of the connector housing 2 provided, on which the partition wall 13 is available. introduction walls 51 and 52 (to be described below) of the shield case 7 are trained in the slots 16 respectively. 17 to be introduced. Due to the provision of the stepped through holes 14 and the slots 16 and 17 has the partition 13 a greater thickness than the remaining portion of the connector housing 2 , Two positioning tabs 19 are on a bottom wall 18 of the connector housing 2 provided, and they are then used when the connector housing 2 is attached to a printed circuit board (not shown). In the present embodiment, the positioning protrusions 19 diagonally on the connector housing 2 arranged.

The FOT recording section 9 is at the rear portion of the connector housing 2 intended. An upper wall 20 of the FOT recording section 9 is at a lower level than that of the upper wall 21 of the connector mounting portion 8th arranged. The FOT recording section 9 has a pair of FOT recording chambers 22 and 23 on (to respectively record the light emitter FOT 5 and the light-receiving FOT 6 ) provided therein and open at their backsides. The FOT recording rooms 22 and 23 are designed so that they each have the light emitter FOT 5 or the light-receiving FOT 6 so record that the two FOTs 6 and 7 are arranged side by side.

The stepped through holes 10 extend to the respective FOT accommodating chamber 22 respectively. 23 , The FOT recording rooms 22 and 23 stand in connection with the fortification room 10 over the respective stepped through holes 14 , Multiple FOT mounting tabs 24 and a plurality of FOT mounting projections 25 are at each of the FOT recording rooms 22 and 23 intended. Multiple leadframe output ports 26 are also in each of the FOT recording rooms 22 and 23 intended.

The FOT mounting tabs 24 are on the partition 13 provided, and project against this. The FOT mounting tabs 24 are designed so that they each have mounting holes 37 (explained in more detail below), which are in the light-emitting or light-receiving FOT 5 respectively. 6 are provided. These FOT mounting tabs 24 are designed so that they press fit in the mounting holes 37 incarcerated. The FOT mount tabs 25 are on a bottom wall 27 of the FOT recording section 9 provided, and project against this. The FOT mount tabs 24 serve the light emitter FOT 5 and the light-receiving FOT 6 to hold in the FOT recording room 22 respectively. 23 are included. The ladder frame launch ports 26 are in the bottom wall 27 of the FOT recording section 9 provided, and are formed substantially slit-shaped. The ladder frame launch ports 26 are designed so that they each have ladder frames 34 (explained in detail below) of the light-emitting FOT 5 respectively. 6 to match. The ladder frames 34 are adapted to each in the ladder frame Ausführungsports 26 to be introduced.

A FOT partition 28 is between the FOT recording rooms 22 and 23 intended. The FOT partition 28 serves to prevent crosstalk, and is designed to span over a range between the light emitter FOT 5 and the light-receiving FOT 6 which stands out in the FOT recording room 22 respectively. 23 are included. The FOT partition 28 is on the partition 13 provided, and faces this. The FOT partition 28 goes continuously into the upper wall 21 and the bottom wall 27 above. A distal end 29 the FOT partition 28 is behind the back or surface of the connector housing 2 arranged.

Each of the sleeves 3 has the shape of a cylinder made of metal and has a flange 30 at its one end, the flange 30 serves as a stop. A body of the sleeve 3 has such an outer diameter as to be in the smaller diameter portion of the stepped through-hole 14 in the connector housing 2 can be introduced. The flange 30 has such an outer diameter as to be in the middle diameter portion of the stepped through-hole 14 can be introduced. The thimbles 3 be in the respective, stepped through hole 14 about the respective FOT recording chamber 22 respectively. 23 of the connector housing 2 introduced. Each sleeve is placed in the stepped through hole 14 until its flange is caused to abut against a step portion intermediate between the smaller diameter portion and the middle diameter portion of the stepped through-hole 14 is provided. If the sleeve 3 in this way into the stepped through hole 14 is inserted, stands each section of the sleeve 3 which extends from its other end to the section in the middle, in the mounting space 10 in the connector housing 2 in front.

Each of the light guide parts 4 is made of a transparent synthetic resin having light transmitting properties, and has a main light guiding portion 31 on, and an introduction holding section 33 , The main light guide section 31 has the task to serve as a convex lens, which is provided at one end. The main light guide section 31 is frusto-conical (or in the form of a truncated cone), this shape decreasing from one end to the other in diameter. The main light guide section 31 is arranged so that its one end faces the associated ring fitting (not shown). The main light guide section 31 of the light guide part 4 THAT IS AS THE LIGHT EMITTER FOT 5 is used to light from the light emitter FOT 5 at one end of the associated ferrule (not shown). On the other hand, the main light guide section serves 31 of the light guide part 4 who is in favor of the light-receiving FOT 6 is used, light from one end of the associated ring fitting (not shown) on the light receiving FOT 5 to collect.

The introduction holding section 32 is formed substantially tubular, and is arranged so that it the main light guide section 31 surrounds. The main light guide section 31 is integral with the introduction holding section 32 connected at one end. The introduction holding section 32 is designed to fit in the sleeve 3 can be introduced. A flange 33 serving as a stopper is in a central portion of the insertion holding portion 32 intended. The flange 33 is configured to abut against a step portion formed between the middle diameter portion and the larger diameter portion of the stepped through-hole 14 in the connector housing 2 is provided. The light guide parts 4 be in the respective sleeve 3 (in the respective stepped through hole 14 in the connector housing 2 is provided) via the respective FOT recording chamber 22 respectively. 23 in the connector housing 2 introduced. Each light guide part 4 gets into one of the thimbles 3 introduced until its flange 33 is placed in abutting engagement with the above-described step portion. In the present embodiment, the two light guide parts 4 for the light-emitting or light-receiving FOT 5 respectively. 6 be used a slightly different Total length on (these sections of the two light guide parts 4 that in the thimbles 3 should be introduced, have a mutually different length, as in 1 shown. This is only an example).

The light emitter FOT 5 has the several lead frames 34 for electrical connection to a circuit on the printed circuit board (not shown), a light emitting element (for example an LD or an LED) 35 , and a mold section 36 , The light emitting element 35 is on one of the several lead frames 34 appropriate. The light emitting element 35 is electrically connected to the other lead frame 34 connected. The several mounting holes 37 extend through the outermost lead frame 34 , The mold section 36 has a cover, which the light emitting element 35 and the above-described electrically connecting portions covers, and a translucent resin, which is filled in the cover to the light-emitting element 35 and protect the electrically conductive portions. A window 38 is in the mold section 36 provided, and the light-emitting element 35 lies through this window 38 free. When the light emitter FOT 5 in the FOT recording room 22 is taken, the FOT mounting projections 24 in a press fit in the respective mounting hole 37 attached, thereby preventing the light emitter FOT 5 disengaged from the FOT holding chamber 22 arrives. The light guide part 4 so gets in the window 38 the light emitter FOT 5 introduced that the light emitting element 35 the other end of the main light guide section 31 opposite.

The light receiving FOT 6 has the several lead frames 34 for electrical connection to a circuit on the printed circuit board (not shown), a light receiving element (for example a PD) 39 , and a mold section 36 , The light receiving element 39 is on one of the several lead frames 34 appropriate. The light receiving element 39 is electrically connected to the other lead frames 34 connected. The several mounting holes 37 extend through the outermost lead frame 34 , The mold section 36 has a cover which the light receiving element 39 and covers the above-described electrically connecting portions, and a translucent resin filled in the cover to the light receiving element 39 and to protect the electrically connecting sections. A window 38 is in the mold section 36 provided, and the light receiving element 39 lies through this window 38 free. When the light receiving FOT 6 in the FOT recording room 23 is taken, the FOT mounting projections 24 each in a press fit in the mounting holes 37 held, thereby preventing the light receiving FOT 6 disengaged from the FOT holding chamber 23 arrives. The light guide part 4 gets into the window 38 the light-receiving FOT 6 introduced so that the light receiving element 39 the other end of the main light guide section 31 opposite.

The shielding housing 7 is made so that an electrically conductive metal sheet is pressed, and this shielding 7 has a housing shielding section 40 on, and a FOT shielding section 41 , The housing shielding section 40 and the FOT shielding section 41 are integrally formed with each other. The housing shielding section 40 covers the connector attachment section 8th in order to provide a countermeasure against electromagnetic noise. The housing shielding section 40 has an upper wall 42 on, opposite side walls 43 , and a connecting wall 44 , The upper wall 42 is flat. An elastic holding piece section 45 and a mass pin 46 are on each of the opposite side walls 43 intended. The elastic holding part sections 45 are provided for the purpose that shielding 7 to fix. The mass pins 46 are each inserted into an associated mounting hole of the circuit board (not shown) for grounding, as well as for the purpose of the optical connector 1 to attach according to the invention. The introductory end section 47 for insertion into the groove 11 in the connector housing 2 is on one of the side walls 43 intended. The introductory end section 47 is formed so as to prevent an end portion of the housing shielding portion from being prevented 40 spreads. The connecting wall 44 connects the top wall 42 and the FOT shielding section 41 , A step is between the top wall 42 and the FOT shielding section 41 through the connecting wall 44 available.

The FOT shielding section 41 covers the light emitter FOT 5 and the light-receiving FOT 6 off, in the FOT recording room 22 respectively. 23 to provide a measure for counteracting electromagnetic noise in these FOTs 5 and 6 to provide. The FOT shielding section 41 has an upper wall 48 on, opposite side walls 49 , a back wall 50 , and the introductory walls 51 and 52 , The upper wall 48 is flat. An elastic holding piece section 45 and a mass pin 46 are on one of the side walls 49 as described above for the housing shielding section 40 intended. The back wall 50 lies on the back surfaces of the light emitter FOT 5 or light-receiving FOT 6 opposite, and this back wall 50 has a pair of convex portions 53 and a pair of FOT retaining springs 54 on. A mass pin 46 will be described above with respect to the housing shielding portion 40 described, is on the back wall 50 intended.

The pair of convex sections 53 serves to prevent crosstalk, and is at a central portion of the back wall 50 intended. The pair of convex sections 53 extends up and down, and the two portions are arranged at a predetermined distance from each other. The convex sections 53 jump inward. In the present embodiment, each convex portion 53 essentially semi-cylindrical shape (so as to scatter light). The distal end of the FOT partition 28 that exist between the FOT recording rooms 22 and 23 is provided and projecting rearwardly, is in a gap between the pair of convex portions 53 introduced. The distal end 29 does not touch the convex portions 53 or the back wall 50 , The pair of FOT retaining springs 54 goes against the respective, rear surface of the light emitter FOT 5 or light-receiving FOT 6 pressed. Both the light emitter FOT 5 as well as the light-receiving FOT 6 is by the associated spring 54 pressurized, leaving a gap between the FOTs 5 . 6 and the associated light guide part 4 each can be kept to a minimum. The introductory walls 51 and 52 are each made so that front end portions of the opposite side walls 49 each bent inward. The introductory walls 51 and 52 are below the connecting wall 44 arranged, and are each in the slots 16 respectively. 17 in the connector housing 2 introduced. If the introductory walls 51 and 52 in the slot 16 respectively. 17 are introduced, practice the FOT-retaining springs 54 a respective pressure force.

When the shield case 7 on the connector housing 2 is attached, on which the sleeves 3 , the light guide parts 4 , the light emitter FOT 5 and the light-receiving FOT 6 are mounted, the plurality of elastic holding part section 45 retainingly engaged with the connector housing 2 offset, causing the shielding 7 with respect to the connector housing 2 is held. The introductory walls 51 and 52 of the shielding housing 7 are each in the slot 16 respectively. 17 in the connector housing 2 introduced, and the FOT-retaining springs 54 are each against the light emitter FOT 5 or the light-receiving FOT 6 pressed. The distal end 29 the FOT partition 28 gets into the gap between the two convex sections 53 of the shielding housing 7 introduced.

In the above construction and embodiment, when an optical signal from the light emitter FOT 5 could exit, the transverse optical signal passes through the FOT bulkhead 28 cordoned off. Further, the backward-out optical signal passes through the convex portions 53 and the distal end 29 the FOT partition 28 cordoned off. Therefore, no crosstalk occurs. In the optical connector 1 According to the invention, the occurrence of crosstalk can be prevented. Furthermore, the formation for preventing the occurrence of crosstalk can be provided inexpensively.

at of the present invention different modifications carried out without departing from the subject matter of the invention.

Claims (4)

Optical connector comprising: a light emitter FOT ( 5 ), which is a light emitting element ( 35 ) having; a light-receiving FOT ( 6 ), which is a light receiving element ( 39 ) having; a connector housing ( 2 ) containing a FOT recording section ( 22 . 23 ) in which the light emitter FOT ( 5 ) and the light receiving FOT ( 6 ) are received side by side, and a shielding ( 7 ), the light emitter FOT ( 5 ) and the light receiving FOT ( 6 ) in order to provide a countermeasure against electromagnetic noise for them, characterized in that: a pair of convex portions ( 53 ) on a wall ( 50 ) of the shielding housing ( 7 ) arranged opposite rear surfaces of the light emitter FOT ( 5 ) and the light-receiving FOT ( 6 ); the FOT recording section ( 22 . 23 ) a crosstalk preventing FOT partition ( 28 protruding over an area extending between the light emitter FOT (FIG. 5 ) and the light receiving FOT ( 6 ) extends; and wherein the shielding housing ( 7 ) on the connector housing ( 2 ) is mounted so that it is the light emitter FOT ( 5 ) and the light receiving FOT ( 6 ) and a distal end ( 29 ) the FOT partition ( 28 ) in a gap between the two convex portions ( 53 ) is introduced, and is held in this gap. Optical connector according to claim 1, characterized in that the distal end ( 29 ) the FOT partition ( 28 ) not in contact with the wall ( 50 ) and the convex portions ( 53 ) is located. An optical connector according to claim 2, characterized in that each of the convex portions ( 53 ) is formed substantially semicircular. Optical connector according to one of claims 1 to 3, characterized in that the shielding housing ( 7 ) a housing shielding section ( 40 ) having a connector mounting portion (14) 8th ) of the connector housing ( 2 ), and the connector mounting portion (FIG. 8th ) a groove ( 11 ) into which an end portion ( 47 ) of the housing shielding section (FIG. 40 ) is introduced.