Optical switching connector

Disclosed is an optical switching connector including a ferrule plate, which fixes an end of an optical fiber to a predetermined position, has pin grooves formed in parallel at its both ends, and has at least one of its pin grooves formed to a width enabling horizontal movement of a reference pin, pin holding members which position the reference pin in said pin grooves, and a frame body which houses said ferrule plate and pin holding members. The optical switching connector is characterized in that the pin holding members are provided individually for each pin groove and provision is made at the both sides of the pin grooves of members for pressing the pin holding members corresponding to the pin grooves where the reference pins can move horizontally to the ferrule plate.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an optical switching connector used for 
switching optical paths in an optical fiber line. 
2. Description of the Related Art 
As one of prior art optical switching connectors used for switching optical 
paths of optical fiber lines, there has been known the one as shown in 
FIG. 1a and 1b, disclosed in Japanese Unexamined (Kokai) Patent 
Application Publication No. 63-85522. 
This optical switching connector has a first ferrule 11 and a second 
ferrule 12 arranged with end faces abutting each other. The first ferrule 
11 has two parallel pin holes 13a and 13b, while the second ferrule 12 has 
two parallel pin holes 14a and 14b. In the corresponding pin holes 13a and 
14b and 13b and 14a are inserted reference pins 15 for positioning 
purposes in a manner so as to span the two ferrules 11 and 12. The 
respective ones of the pin holes of each of the first and second ferrules 
11 and 12, that is, 13a and 14a, are formed to a size which will prevent 
horizontal movement of the reference pins 15, while the other pin holes 
13b and 14b are formed with horizontally longer sectional shapes so as to 
allow the reference pins 15 to move horizontally by a predetermined pitch 
P. 
Between the two pin holes 13a and 13b of the first ferrule 11n are fixed 
four optical fibers 17a to 17d of a four-core tape-core line 16 with their 
end faces exposed, while between the two pin holes of the second ferrule 
12 are fixed the two optical fibers 19a and 19b of a two-core line, for 
example. 
If the first ferrule 11 is fixed and the second ferrule 12 is made to be 
movable horizontally (the reverse is also possible), then in the condition 
with a force in the direction of the arrow A applied to the second ferrule 
12 as shown in FIG. 1a, the two optical fibers 19a and 19b of the second 
ferrule 12 are connected with the two optical fibers 17a and 17b on one 
side of the first ferrule 12 to form optical paths. Thereafter, if force 
in the direction of the arrow B is applied to the second ferrule 12 as 
shown in FIG. 1b, this moves horizontally and the optical fibers 17c and 
17d on the other side of the first ferrule 11 to form optical paths. 
The optical switching connector performs switching of optical paths in the 
above manner. 
The above-mentioned first and second ferrules are required to have high 
dimensional precision, and thus are comprised as the optical switching 
connector shown in FIG. 2. That is, the optical switching connector 21 is 
comprised of a ferrule plate 22, a pin holding member 23, a frame body 24, 
and screws 25a and 25b. 
The ferrule plate 22 fixes the end portion of the optical fiber 17 to 
predetermined position, has pin grooves 26a and 26b formed in parallel at 
its both sides, has one of the pin grooves 26a formed to a width 
preventing horizontal movement of the reference pin 15, and has the other 
pin grooves 26b formed to a width enabling horizontal movement of the 
reference pin 15. The pin holding member 23 serves as a cover for 
positioning the reference pins 15 in the pin grooves 26a and 26b, so the 
pin holes are formed by the pin holding member 23 and the pin grooves 26a 
and 26b. The ferrule plate 22 and the pin holding member 23 are housed in 
the frame body 24 and screws 25a and 25b are used to fasten them to form a 
single body. 
Note that the pin grooves 26a and 26b sometimes are both formed to widths 
enabling the reference pins 15 to move horizontally by a predetermined 
pitch. In this case, the pin grooves of the opposing optical switching 
connector are both formed to widths preventing horizontal movement. 
This type of conventional optical switching connector has the pin holding 
member 23 formed of a single plate which is fastened by screws 25a and 25b 
from directly above the pin grooves 26a and 26b. As a result, bending of 
the pin holding member 23 occurs at the wide width pin groove 26b as shown 
by the dotted line A and there are cases where the reference pin 15 cannot 
be inserted and cases where even when insertable, the resistance to 
horizontal movement is great and the switching operation cannot be 
performed smoothly. 
Since the pin holding member 23 is a single plate, in the case where the 
diameter of the reference pin 15 is larger than the design value or the 
case where the width of the pin groove 26a is smaller than the design 
value, as shown in FIG. 3, the pin holding member 23 becomes slanted, the 
switching direction and the direction of arrangement of the optical fibers 
deviate from each other, and the connection loss increases. 
Further, as shown in FIG. 4, in the case where the diameter of the 
reference pin 15 is smaller than the design value or the case where the 
width of the pin groove 26a is larger than the design value, the position 
of the reference pin 15 is uncertain, as a result, the connection loss 
also increases. 
SUMMARY OF THE INVENTION 
The present invention provides an optical switching connector which 
resolves the problems in the prior art mentioned above. 
An object of the present invention is to provide an optical switching 
connector enabling a smooth switching operation. 
Another object of the present invention is to provide an optical switching 
connector wherein a connection loss is reduced. 
According to the present invention, it is constituted as an optical 
switching connector including a ferrule plate, which fixes an end of an 
optical fiber to a predetermined position, has pin grooves formed in 
parallel at its two ends, and has at least one of its pin grooves formed 
to a width enabling horizontal movement of a reference pin, pin holding 
members which position the reference pins in said pin grooves, and a frame 
body which houses the ferrule plate and pin holding members, characterized 
in that the pin holding members are provided individually for each pin 
groove and provision is made at the two sides of the pin grooves of a 
means for pressing the pin holding members corresponding to the pin 
grooves where said reference pins can move horizontally to the ferrule 
plate. 
Another feature of the present invention is that in such an optical 
switching connector, the thickness of the bottom portion of the frame body 
is at least the thickness of the ferrule plate. 
In the present invention, a pin holding member is provided separately for 
each pin groove so as to reduce the connection loss caused by dimension 
error of the reference pins and pin grooves. Further, the pin holding 
member corresponding to the pin groove where the reference pin can move 
horizontally is pressed to the ferrule plate at the two sides of the pin 
groove so as to eliminate the bending caused by the fastening of the pin 
holding member and enable a smooth switching operation. 
Further, the thickness of the bottom portion of the frame body is made not 
less than the thickness of the ferrule plate so as to eliminate the 
bending of the frame body caused by the fastening and to reduce the 
increase of connection loss.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Preferred embodiments of the present invention will be explained in detail 
with reference to the drawings. 
FIG. 5 to FIG. 7 show embodiments of optical switching connectors according 
to the present invention, wherein portions the same as the previously 
explained FIG. 2 are given the same reference numerals. 
The optical switching connector 21 of FIG. 5 has the pin holding member 
divided into a pin holding member 23a which holds down the reference pin 
15 in the narrow width pin groove 26a and the pin holding member 23b which 
holds down the reference pin 15 in the wide width pin groove 26b, has the 
pin holding member 23a on the narrow width pin groove 26a pressed to the 
reference pin 15 by the screw 25a and has the pin holding member 23b of 
the wide width pin groove 26b side is eliminated and the switching 
operation can be performed smoothly. 
When 500 switching operations were performed using the optical switching 
connector of the above construction, the amount of change of the 
transmission loss was no more than 0.2 dB. 
The optical switching connector 21 of FIG. 6 has the reference pin 15 in 
the narrow width pin groove 26a pressed by the screw 25a. That is, in this 
embodiment, the screw 25a serves also as a pin holding member. The rest of 
the construction is the same as in FIG. 5. 
The optical switching connector 21 of FIG. 7 has the thickness T of the 
bottom portion of the frame body 24 made the same as the thickness U of 
the ferrule plate 22 to prevent the ferrule plate 22 from bending as shown 
by the dotted line B. 
In this type of optical switching connector, the thickness U of the ferrule 
plate 22 must be 4 mm. As opposed to this, the thickness T of the bottom 
portion of the frame body 24 was changed to investigate the increase of 
the loss L (dB) of the optical switching connector. The results are shown 
in Table 1. 
TABLE 1 
______________________________________ 
Thickness T of bottom 
of frame body Increment of loss L 
(mm) (dB) 
______________________________________ 
1.5 5.10 
2.0 2.87 
3.0 0.72 
4.0 0 
______________________________________ 
If by this the thickness T of the bottom portion of the frame body is made 
the same or greater than the thickness U of the ferrule plate, it is 
understood that the increase of loss L caused by the bending of the 
ferrule plate can be eliminated. When the thickness T of the bottom 
portion of the frame body is 4.0 mm, if the screws 25a, 25b1, and 25b2 are 
used to fix the ferrule plate 22 by an axial force of up to 1.5 kg, the 
amount of bending of the bottom portion of the frame body 24 caused by the 
axial force becomes no more than 1 .mu.m and therefore the bending of the 
ferrule plate 22 can be almost completely eliminated and the increase in 
the transmission loss caused by the bending can also be almost completely 
eliminated. 
Note that in the embodiment, use is made of stainless steel for the frame 
body, but if use is made of a superhard alloy or ceramic for the frame 
body, the thickness of the bottom portion of the frame body may be made 
thinner than in the above case. 
As explained above, according to the present invention, the bending of the 
pin holding member corresponding to the pin groove where the reference pin 
can move horizontally is eliminated, and thus the switching can be 
performed smoothly. Further, the reference pins can be fixed securely 
without regard to dimensional error, and therefore the positioning by the 
reference pins becomes more accurate and it is possible to form an optical 
switching connector with very little connection loss. Further, if the 
thickness of the bottom portion of the frame body is made at least the 
thickness of the ferrule plate, the bending of the ferrule plate almost 
completely disappears and in this regard too it is possible to reduce the 
connection loss.