JP4190017B2 - Light outlet - Google Patents

Description

  The present invention relates to an optical outlet to which an optical fiber cable terminated with an optical connector is connected.

With the development and spread of ultra-high-speed Internet connection technology, the introduction of Internet connection services that use optical fiber cables as access lines, so-called FTTH (Fiber To The Home), is also progressing in ordinary houses.
In FTTH, an optical fiber cable extending from an optical fiber accommodation facility constructed by an FTTH provider is drawn into a user's home and connected directly or as necessary to a line terminator called a media converter or ONU, and an electrical signal is converted into an electrical signal. After being converted to, it is connected to a computer or the like.
When installing a line terminator in a room, the optical fiber is pulled out from the wall of the room, cut to the required length to the installation site of the line terminator, etc., terminated with an optical connector, Connected to an optical receptacle. In order to pull out the optical fiber from the living room wall, a round hole is provided in the wiring device plate provided in the living room wall, or a telephone chip having a through hole is provided in the living room wall, and the wiring device plate and the telephone chip are inserted through the round holes. It was common to pull out an optical fiber.
However, in this type of conventional method, since the optical fiber extending from the outdoor optical fiber accommodation facility is directly connected to the line terminator, etc., the optical fiber after determining the installation position of the line terminator etc. in the existing house in advance. Although it is good to perform fiber entry work, if the installation position of the line terminator etc. cannot be determined in advance, such as in a new house, the length of the optical fiber can not be determined, so appropriate wiring processing cannot be performed. was there.
In other words, since the length of the optical fiber drawn from the wall cannot be determined, if the optical fiber is short, it will not reach the line terminator, etc., and connection will be impossible. If they are bundled, the glass fiber core may be broken and communication may be disabled.
Further, the optical fiber drawn into the room is easily damaged by being stepped on or bent by a person, and a disconnection accident may occur. However, in the unlikely event of a break in the room, the conventional construction method cannot be separated from the optical fiber that penetrates the wall and extends to the outside, so the replacement work over the entire length using a new optical fiber from the outside is required. There was a maintenance problem that had to be done.
In addition, when changing the layout of the room, there is also an operational problem that it is not possible to move the line terminator freely by changing the routing of the optical fiber.
Therefore, an optical fiber outlet (optical outlet) is provided at the optical fiber drawing position, the optical fiber drawn into the wall from the outside is received by the optical outlet, and the line terminator provided in the living room and the optical outlet A method of detachably connecting between the two using an optical patch cord of any length is conceivable. As conventional optical outlets, there are known an embedded optical outlet disclosed in JP-A-1-297604 and an optical fiber wiring device disclosed in JP-A-63-257701.
However, although the conventional optical outlet is suitable for use in a local area network (LAN) using a plastic optical fiber called POF, it is not suitable for connection of a silica-based single mode optical fiber used for FTTH. It was.
That is, unlike POF, silica-based optical fibers have severe restrictions on the minimum bending radius, and bending the optical fiber beyond the prescribed minimum bending radius may cause breakage of the core wire or significant transmission loss.
However, in the optical outlet disclosed in the above-mentioned published patent gazette, the optical fiber cable wired inside the wall is a wall surface because of the configuration in which the optical fiber is connected via a single optical connector or an optical relay adapter. Must be connected to these optical connectors and optical repeater adapters at a right angle or at a fixed angle. Therefore, the optical fiber cable wired inside the wall needs to be bent suddenly in the wall and routed in a narrow space in the wall.
In applications where the transmission loss requirement of the optical fiber is not severe, such as a local area LAN, it is possible to use a POF that is relatively flexible and can bend with a small diameter as an optical fiber. It is also possible to perform wiring after processing. However, silica optical fibers suitable for low loss and high-speed transmission are virtually impossible to install with a minimum bending radius defined in the optical fiber in a narrow space in the wall. The outlet for an optical fiber disclosed in the above-mentioned published patent publication cannot be used for FTTH using a quartz optical fiber.

The present invention has been made in view of the above-described circumstances, and is suitable for FTTH that enables wiring in a narrow space in a wall without difficulty even with a silica-based optical fiber having a severe bending radius. The purpose is to provide an outlet.
In order to achieve the above object, the present invention provides a body mounted on a wall surface of a room via a wiring device mounting frame, and a device side provided on the front side of the body and connected to a device-connecting optical connector from the room side. An optical receptacle, a trunk-side optical receptacle provided on the back side of the body, to which a main-line connecting optical connector extending the trunk-side optical fiber is connected, and the device-side optical receptacle and the trunk-side optical receptacle. And signal transmission means for transmitting signals between them.
According to the present invention having the above-described configuration, the apparatus-side optical receptacle and the trunk-side optical receptacle are separated and independent, so that the trunk-side optical receptacle is not restricted by the connection angle of the optical fiber to the apparatus-side optical receptacle. It is possible to arbitrarily set the connection angle of the optical connector for trunk line connection. Therefore, it is possible to freely design the trunk-side optical fiber extending from the trunk-connecting optical connector so as not to be bent suddenly in the wall, and it can also be applied to the connection of a silica-based optical fiber used for FTTH.
Further, the present invention is characterized in that an optical receptacle compatible with an SC connector is used for the device side optical receptacle and the main line side optical receptacle.
With this configuration, the SC connector that is most widely used as an optical connector for use in an FTTH service line terminator for general housing can be used as it is, and versatility is improved. Moreover, since the user can easily connect between the equipment side optical receptacle and the line terminator called ONU or media converter using a commercially available SC type optical patch cord, the optical terminal in the room It is possible to respond flexibly and flexibly to equipment layout changes.
As the signal transmission means, it is preferable to use an optical fiber core or an optical fiber. As a result, the component cost is low, and simple and compact assembly is possible.
In this case, the body has an internal space in which an optical fiber core or an optical fiber as a signal transmission means connected to the device-side optical receptacle and the trunk-side optical receptacle can be bent and stored. Is preferred.
Optical fiber cores or optical fiber strands are thin, flexible, and have a small minimum bending radius because structures such as an optical fiber cable and an optical fiber cord used for outdoor and indoor wiring are omitted. Therefore, it is possible to reduce the size of the body, and even in a narrow space within the further reduced size of the body, between the optical receptacles without restricting the arrangement position of the device-side optical receptacle and the trunk-side optical receptacle. Can be connected.
When the optical connector of the present invention is used for the FTTH described above, it is preferable to use a silica-based single mode optical fiber or a silica-based single mode optical fiber.
In the present invention, a signal converter capable of mutually converting an optical signal and an electrical signal is used as the signal transmission means, and an electrical signal is transmitted between the device-side optical receptacle and the trunk-side optical receptacle. You can also.
With this configuration, the relative position of each optical receptacle is almost unrestricted compared to the case where an optical fiber or the like is used for signal transmission between the optical receptacles, and it is possible to cope with thinning of the body. In addition, when a signal is transmitted inside the body, it passes through an electrical signal once. Therefore, it is easy to amplify and shape the waveform using a simple electronic circuit. Therefore, it is possible to freely cope with a design suitable for an optical access line that requires a large amount of data.
In addition, with the configuration using the signal converter, the optical fibers connected to the respective optical receptacles can be of different types. For example, the optical fibers connected to the device-side optical receptacles include: It is also possible to use a POF that is easy to handle.
Furthermore, according to the configuration using the signal converter, after the optical signal is converted into an electrical signal in the body, the signal can be branched and combined using an electronic circuit, and a single optical access line ( It is also possible to provide a plurality of device-side optical receptacles with respect to the trunk-side optical receptacle) and to input / output a plurality of optical signals.
Moreover, the optical outlet of this invention can also be comprised as follows.
(A) In an optical outlet in which a connector insertion portion having an open bottom surface is formed on the front side of the body, and a device-side optical receptacle is disposed in the connector insertion portion,
A shutter extending below the device-side optical receptacle is provided inside the connector insertion portion, and the light beam emitted from the device-side optical receptacle is blocked by this shutter.
With this configuration, for example, even when a child looks into the connector insertion portion from below the body, the shutter blocks the light beam emitted from the device-side optical receptacle. There is no risk of entering the eye, improving safety.
(B) The shutter is formed of a shape memory alloy or an alloy such as stainless steel having high spring characteristics, and is restored to a position where the light beam emitted from the device-side optical receptacle is blocked at room temperature.
Thereby, the shutter can be reliably restored to the above position.
(C) The optical connector for connecting devices to be inserted into the connector insertion portion has a resin connector body,
The shutter is configured to be bent in contact with a connector main body inserted into the connector insertion portion.
If comprised in this way, even if optical conducting members, such as a ferrule, are exposed from the optical connector for apparatus connection, there is no possibility that the optical conducting member will contact a shutter at the time of insertion, and damage to the optical conducting member can be avoided.
(D) It is set as the structure which provided the confirmation window which can visually recognize the optical connector for apparatus connection inserted in the connector insertion part in the front wall part of a connector insertion part.
This confirmation window allows you to insert into the connector insertion part while checking the position of the optical connector for connecting the equipment, so that you can connect to the optical receptacle on the equipment side installed in the connector insertion part accurately and smoothly. It becomes.
(E) The connector insertion portion is provided with a protective bushing that can be inserted and removed from the opening.
When the device-connecting optical connector is not connected to the device-side optical receptacle, the opening of the connector insertion portion can be blocked by this protective bushing to prevent dust from entering.
(F) The protective bushing has a bushing body and a knob portion extending from the bushing body,
The knob portion is configured to be exposed downward from the opening of the connector insertion portion when the protective bushing is attached to the connector insertion portion.
By exposing the knob portion from the opening of the connector insertion portion, the protective bushing can be easily removed.
(G) The protective bushing is formed of an elastic member such as a rubber or a thermoplastic elastomer that integrally forms the bushing body and the knob portion with a thermoplastic resin and elastically contacts the inner wall of the connector insertion portion on the outer periphery of the bushing body. It can be set as the structure which provided the sealing part which becomes.
By providing a sealing part made of an elastic member such as rubber or thermoplastic elastomer on the outer periphery of the bushing main body, this sealing part can be tightly closed to the inner wall of the connector insertion part, and the connector insertion part can be closed without a gap, Even fine dust can be reliably prevented from entering.
(H) It is configured to include a protective cover that is detachable from the opening of the connector insertion portion on the front side of the body to a lower position and covers the knob portion of the protective bushing exposed from the opening.
If the protective cover is provided in this way, there is no possibility that anything touches the knob portion of the protective bushing exposed from the opening, and the protective bushing can be kept attached for a long period of time. For example, it is possible to avoid the possibility of the protective bushing falling off due to a child's mischief.
(I) In an optical outlet in which an optical connector for connecting a device having a resin connector body is inserted from a connector insertion portion,
The protective cover is configured to cover the connector main body exposed from the opening of the connector insertion portion in a state where the optical connector for device connection is inserted into the connector insertion portion.
The protective cover can also have a function of preventing the connector body from being pulled out in a state in which the device connection optical connector is connected. Do not fall off.
(J) A connector having a detachable cleaning adapter in the connector insertion portion, the cleaning adapter being mounted in the connector insertion portion, and being positioned on the same straight line as the light conducting portion of the device side optical receptacle The through-hole is configured such that a stick-like cleaner can be inserted from the outside.
In general, an apparatus-side optical receptacle in which an apparatus-connecting optical connector has not been connected for a long period of time needs to be connected to the apparatus-connecting optical connector after the optical conducting portion is cleaned with a cleaner. However, it is difficult to determine the position of the optical conducting portion of the device side optical receptacle disposed in the connector insertion portion from the outside. This is especially true when the light outlet is installed in a low place on the wall of the room.
Therefore, if the cleaning adapter is attached to the connector insertion part and a stick-shaped cleaner is inserted through the through hole of the adapter, the through hole is positioned on the same straight line as the light conducting part of the device side optical receptacle. The cleaner can be accurately guided to the light conducting portion and easily cleaned.
(K) In an optical outlet in which a connector insertion part having an open bottom surface is formed on the front side of the body, and a device-side optical receptacle is disposed in the connector insertion part.
A protective member that can be moved in and out is provided at a position facing the opening of the connector insertion portion.
(L) A latch mechanism that locks the protective member while being pushed into the body is provided.
(M) A protective bushing that can be inserted / removed from the opening is provided in the connector insertion portion,
The protective member is configured to support the protective bushing inserted into the connector insertion portion from below and prevent the connector from coming off from the connector insertion portion.
(N) A plurality of device side optical receptacles are provided,
Inside the body, there is means that can distribute and mix signals between the equipment side optical receptacle and the main line side optical receptacle,
The optical signal input from the main line side optical receptacle is distributed and output to a plurality of apparatus side optical receptacles, and the plurality of optical signals input from the plurality of apparatus side optical connectors are mixed and output to the main line side optical connector. The configuration.
Here, a splitter (optical splitter) can be used as means for distributing and mixing signals between the device-side optical receptacle and the trunk-side optical receptacle.
(O) A plurality of device side optical receptacles are provided,
Inside the body, there is means that can demultiplex and multiplex signals between the equipment side optical receptacle and the main line side optical receptacle,
Multiplexed optical signals input from the main line side optical receptacle are separated and output to a plurality of device side optical receptacles of different transmission types, and a plurality of optical signals input from a plurality of apparatus side optical connectors are connected to the main line. The output is synthesized and output to the side optical connector.
Here, a WDM (optical demultiplexer) can be used as means for demultiplexing and multiplexing signals between the device side optical receptacle and the main line side optical receptacle.

FIG. 1A is a diagram showing an optical outlet according to the first embodiment of the present invention. Specifically, FIG. 1A is a front view showing the optical outlet in a state of being mounted on a wiring fixture mounting frame and attached to a wall surface.
FIG. 1B is also a side view.
FIG. 1C is also a side sectional view.
FIG. 2A is a view showing the optical outlet according to the second embodiment of the present invention, and more specifically, is a front view showing the optical outlet in a state where it is attached to the wiring fixture mounting frame and attached to the wall surface.
FIG. 2B is also a perspective view.
FIG. 2C is a cross-sectional side view of the same.
FIG. 3A is a view showing an optical outlet according to a third embodiment of the present invention, and more specifically, is a front view showing the optical outlet in a state of being attached to a wiring fixture mounting frame and attached to a wall surface.
FIG. 3B is a side view of the same.
FIG. 3C is also a side sectional view.
FIG. 4A is a front view showing an optical outlet according to the fourth embodiment of the present invention.
FIG. 4B is also a bottom view.
FIG. 4C is a sectional side view of the same.
FIG. 5 is a side sectional view showing an optical outlet according to the fifth embodiment of the present invention.
FIG. 6 is an enlarged side sectional view showing the function of the shutter provided in the optical outlet according to the fifth embodiment of the present invention.
FIG. 7 is a front view showing a confirmation window provided in the optical outlet according to the fifth embodiment of the present invention.
FIG. 8 is a side sectional view for explaining a protective bushing provided in the optical outlet according to the fifth embodiment of the present invention.
FIG. 9A is a front view showing a protective bushing.
FIG. 9B is a left side view of the same.
FIG. 9C is a right side view of the same.
FIG. 9D is a bottom view of the same.
9E is a cross-sectional view taken along line AA in FIG. 9A.
9F is a cross-sectional view taken along line BB in FIG. 9D.
10A and 10B are front views showing the optical outlet with the protective cover attached.
FIG. 10C is a front view of the protective cover.
FIG. 10D is a bottom view of the protective cover.
FIG. 11 is a side sectional view showing a cleaning adapter provided in the optical outlet according to the fifth embodiment of the present invention.
FIG. 12A is a front view showing the cleaning adapter.
FIG. 12B is also a left side view.
FIG. 12C is a right side view of the same.
FIG. 12D is also a bottom view.
12E is a cross-sectional view taken along line CC of FIG. 9A.
12F is a cross-sectional view taken along the line DD of FIG. 9D.
13 and 14 are side sectional views showing an optical outlet according to the sixth embodiment of the present invention.
FIG. 15 is a side sectional view showing an optical outlet according to the seventh embodiment of the present invention.
FIG. 16 is a side sectional view showing an optical outlet having a configuration in which the trunk side optical receptacle is omitted.

A preferred embodiment according to the present invention will be described with reference to the drawings.
[First Embodiment]
1A to 1C are diagrams illustrating an optical outlet according to a first embodiment of the present invention.
The optical outlet includes a body 10, a device-side optical receptacle 11, a trunk-side optical receptacle 12, and a relay optical fiber 13 as a signal transmission unit.
The body 10 can be freely attached to and detached from a standardized existing wiring fixture mounting frame 1 like an outlet or a switch. For this purpose, an engaging portion (not shown) to the wiring fixture mounting frame 1 is formed on the periphery of the body 10, and the inside of the body 10 forms a hollow portion 10a. A device-side connector insertion portion 10b penetrating vertically is formed on the wall surface on the front side of the body 10, and the device-side optical receptacle 11 is disposed inside the device-side connector insertion portion 10b. Further, a trunk-side connector insertion portion 10c penetrating vertically is formed on the wall surface on the back side of the body 10, and a trunk-side optical receptacle 12 is disposed inside the trunk-side connector insertion portion 10c. is there. The device-side optical receptacle 11 and the main line-side optical receptacle 12 are connected by a relay optical fiber 13.
The apparatus side optical receptacle 11 is connected to the apparatus side optical fiber 2 along the indoor wall 100 from below, and the main line side optical receptacle 12 is connected to the main line side optical fiber 4 along the indoor wall 100 from below. Here, both the device side optical receptacle 11 and the trunk side optical receptacle 12 are adapted to the SC connector most widely used as an optical connector used in a line terminating device for FTTH service for general houses. As a result, a commercially available optical patch cord terminated with the SC connector 3 (device connection optical connector) can be used for the device side optical fiber 2. However, it goes without saying that the device-side optical fiber 2 connected to the device-side optical receptacle 11 is not limited to a commercially available optical patch cord. Also, the main line side optical fiber 4 connected to the main line side optical receptacle 12 can also be terminated with a versatile SC connector 5 (optical connector for main line connection), so the main line side can be easily used without using a special tool. The connection work to the optical receptacle 12 can be performed.
When the optical outlet according to the present embodiment is used for FTTH, the trunk-side optical fiber 4 connected to the trunk-side optical receptacle 12 is generally a quartz single-mode optical fiber. In this case, it is preferable to use a silica-based single mode optical fiber core or a silica-based single mode optical fiber as the relay optical fiber 13. However, it is not limited to this.
The relay optical fiber 13 provided in the body 10 is not subjected to stress such as tension, twisting, bending, and compression due to external force. Therefore, tensile strength materials and sheaths such as optical fiber cables and optical fiber cords used for outdoor and indoor wiring are used. Such a structure is unnecessary. Therefore, an optical signal can be transmitted without being attenuated by using a thin, flexible and simple optical fiber core or an optical fiber.
For example, some silica-based single-mode optical fiber core wires called “buffer wires” have a bending radius of 20 mm, and by using this as the repeater optical fiber 13, the body 10 can be hollow without increasing its size. It becomes possible to connect the apparatus side optical receptacle 11 and the main line side optical receptacle 12 in the part 10a. Note that both ends of the relay optical fiber 13 are connected to the equipment-side optical receptacle 11 and the trunk-side optical receptacle 12 via ferrules 14 and 15.
The hollow portion 10a of the body 10 has a thickness that allows the relay optical fiber 13 to be curved and disposed. Of course, the repeater optical fiber 13 uses a quartz single-mode optical fiber core wire or a quartz single-mode optical fiber having a small bending radius, so that the thickness of the hollow portion 10a can be small.
A decorative plate 6 is detachably mounted on the front side of the wiring fixture mounting frame 1, and the body 10 of the optical outlet is covered by the decorative plate 6 except for the connection portion of the device-side optical fiber 2. An embedded outlet box 7 is embedded in the interior wall 100 to which the wiring device mounting frame 1 is mounted.
Then, the main line side optical fiber 4 drawn into the indoor wall 100 connects the SC connector 5 provided at the end thereof to the main line side optical receptacle 12 from below. On the other hand, the device provided in the living room and the optical outlet of the present embodiment are connected by the device-side optical fiber 2. That is, the device side optical fiber 2 connects the SC connector 3 provided at the end thereof to the device side optical receptacle 11 from below. These optical fibers 2 and 4 can be easily connected with one touch.
The optical signal incident from the main line side optical receptacle 12 is guided to the curved relay optical fiber 13 through the ferrule 15 and transmitted to the equipment side optical receptacle 11 through the ferrule 14. On the contrary, the optical signal from the device side that has entered the device-side optical receptacle 11 is transmitted to the trunk-side optical receptacle 12 via the ferrule 14, the relay optical fiber 13, and the ferrule 15, so that bidirectional optical communication is not hindered. Done.
Here, since the main line side optical receptacle 12 is configured to connect the main line side optical fiber 4 from below along the indoor wall 100, the main line side optical fiber 4 does not abruptly bend the narrow space in the wall. Can be freely routed. In addition, there is no risk that dew condensation water or the like on the back of the wall will enter the body 10 through the trunk-side optical fiber 4, and long-term durability performance can be ensured even in a highly airtight apartment house.
Further, since the device-side optical receptacle 11 is also configured to connect the device-side optical fiber 2 from below, the device-side optical fiber 2 can be neatly routed in the living room and finished with good appearance. Moreover, since the device-side optical fiber 2 can be lowered along the indoor wall 100, a safe wiring state can be formed with less risk of tripping or hooking.
Furthermore, even if the device-side optical fiber 2 in the living room is broken, it can be easily replaced by the end user himself. Therefore, it is possible to handle delicate silica-based optical fibers practically even in ordinary houses without specialists. It becomes possible.
In addition, the device-side optical receptacle 11 can suppress dust accumulation and splash intrusion by arranging the receiving port of the device-side optical fiber 2 downward.
[Second Embodiment]
2A to 2C are views showing an optical outlet according to the second embodiment of the present invention. In these figures, the same or corresponding parts as those shown in FIGS. 1A to 1C are denoted by the same reference numerals.
As shown in FIG. 2B, the optical outlet of the present embodiment has a configuration in which the main line side optical receptacle 12 is provided on the back side of the body 10 by being inclined with respect to the vertical line. Note that the trunk-side optical receptacle 12 is disposed substantially parallel to the wall surface of the indoor wall 100, and therefore the trunk-side optical fiber 4 can be routed along the indoor wall 100 as in the first embodiment. It is the same. The embedded outlet box 7 embedded in the back side of the indoor wall 100 is a large square box having an internal space in which the trunk side optical fiber 4 can be swung and stored.
According to the optical outlet of the present embodiment, the extra length processing of the main optical fiber 4 can be performed without re-wiring even if the extra length is generated in the main optical fiber 4 drawn along the indoor wall 100. Can be performed in the embedded outlet box 7, and wiring work is further facilitated.
Moreover, the body 10 is formed in the size of a ready-made three-module wiring device, and can be attached to the wiring device mounting frame 1 in any combination with the body 10 of the optical outlet according to the present embodiment and other wiring devices. It is as. In FIG. 2, two analog telephone modular outlets 20 and an optical outlet body 10 according to this embodiment are provided side by side on the wiring device mounting frame 1.
[Third Embodiment]
3A to 3C are views showing an optical outlet according to the third embodiment of the present invention. In these drawings, the same or corresponding parts as those shown in FIGS. 1A to 1C are denoted by the same reference numerals.
The optical outlet of the present embodiment is configured by incorporating a device-side optical receptacle 11, a trunk-side optical receptacle 12, and a relay optical fiber 13 as a signal transmission means in a body 10 having a size of an off-the-shelf two-module wiring apparatus. It is.
Accordingly, the wiring fixture mounting frame 1 can be attached to the body 10 of the optical outlet according to the present embodiment and one other wiring fixture, respectively. For example, a modular outlet for analog telephones is attached to the wiring fixture mounting frame 1. 20 and an optical outlet according to the present embodiment can be easily installed. Further, using the wiring module mounting frame 1 for mounting two modules provided in the existing house, one of the existing modular telephone outlets for analog telephone lines is removed, and the body of the optical outlet according to this embodiment is used instead. By installing 10, the FTTH service introduction work in the existing house can be easily realized.
[Fourth Embodiment]
4A to 4C are views showing an optical outlet according to the fourth embodiment of the present invention. In these drawings, the same or corresponding parts as those shown in FIGS. 1A to 1C are denoted by the same reference numerals.
The optical outlet according to the present embodiment is an optical / electrical converter (hereinafter referred to as an optical / electrical converter) that can convert an optical signal and an electrical signal to a signal transmission unit that transmits a signal between the device-side optical receptacle 11 and the trunk-side optical receptacle 12. , O / E converters) 31 and 32, and the apparatus side optical receptacle 11 and the trunk side optical receptacle 12 are transmitted with an electrical signal.
Here, the O / E converter 31 is formed integrally with the device side optical receptacle 11, while the O / E converter 32 is formed integrally with the main line side optical receptacle 12. Each of the O / E converters 31 and 32 is connected by a conducting wire 33.
The optical signal incident from the device side optical fiber 2 or the main line side optical fiber 4 is converted into an electric signal by the O / E converter 31 or 32, and the other O / E converter 32 or 31 is passed through the conductor 33. To be converted into an optical signal again.
Since the communication data converted into the electrical signal can be transmitted at any steep angle using the conductor 33, the optical receptacles 11 and 12 should be arranged at appropriate positions regardless of the relative positions of each other. Can do.
In addition, since the O / E converters 31 and 32 generally have a function of a relay amplifier, even if an optical signal incident from the trunk side optical fiber 4 is attenuated by long-distance transmission, it is electrically amplified. It can be shaped and an enhanced optical signal can be output to the device-side optical fiber 2. A similar amplifying action also works for transmission in the reverse direction.
Therefore, there is an advantage that stable optical communication is possible without worrying about transmission loss, even in an application where the private premises are further routed from the optical outlet by an optical fiber.
In addition, by changing the type of the O / E converter 31, it is possible to use a POF that is easy to handle as the device-side optical fiber 2.
Further, by providing a multiplexing modulation / demodulation circuit 34 between the O / E converters 31 and 32, a plurality of device-side optical receptacles 11 are provided, and signals transmitted from the plurality of device-side optical receptacles 11 are multiplexed. It can also be processed and superimposed on the trunk side optical receptacle 12 for transmission.
For example, when services that take advantage of the high speed of optical fiber in the future, such as multiplexing of voice communication and video distribution / data communication, are introduced, even if there is only one access line, an optical outlet is provided for each application. In addition, optical signals can be distributed and connected from a plurality of outlets to a plurality of optical communication devices.
[Fifth Embodiment]
5 to 12F are views showing an optical outlet according to the fifth embodiment of the present invention. In these drawings, the same or corresponding parts as those shown in FIGS. 1A to 1C are denoted by the same reference numerals.
As shown in FIG. 5, the optical outlet according to the present embodiment includes a thin plate-like shutter 40 having flexibility inside the device-side connector insertion portion 10b. As shown in the enlarged view of FIG. 6A, the shutter 40 has a base 40a fixed to the back surface of the device-side optical receptacle 11, and an intermediate portion 40b extending from the base 40a is connected to the device-side optical receptacle 11. It is arranged at a position below the ferrule 14 (light conducting portion), that is, a position that blocks the light beam emitted from the ferrule 14. The shutter 40 is formed of a shape memory alloy and is adjusted so as to be restored to the position at room temperature.
By providing the shutter 40, for example, even when a child looks into the device-side connector insertion portion 10b from below the body 10, the shutter 40 blocks the light beam emitted from the ferrule 14, There is no risk of the light beam entering the child's eyes, and safety is improved.
Further, as shown in FIG. 6B, when the SC connector 3 that is an optical connector for equipment connection is inserted into the equipment side connector insertion portion 10b from below, the connector main body 3a that forms the outer frame of the SC connector 3 contacts the shutter 40. Contact and bend it back. As a result, the SC connector 3 can be connected to the device-side optical receptacle 11 without the shutter 40 coming into contact with the ferrule 3b (light conducting member) exposed from the SC connector 3.
FIG. 6C shows a state where the SC connector 3 is properly connected to the device-side optical receptacle 11.
When the SC connector 3 is pulled out from the connection state shown in FIG. 6C and the connection with the device-side optical receptacle is released, the shutter 40 made of a shape memory alloy or an alloy such as stainless steel having high spring characteristics is again shown in FIG. 6A. The light beam emitted from the ferrule 14 is restored to the position where it is blocked.
In this embodiment, as shown in FIGS. 5, 7A, and 7B, a confirmation window 41 made of transparent plastic is provided on the front wall portion of the device-side connector insertion portion 10b. Specifically, a confirmation window 41 is provided in a range from the lower end of the device-side connector insertion portion 10b to a predetermined height, and the SC connector 3 inserted into the device-side connector insertion portion 10b is connected to the confirmation window 41. Can be seen through.
The SC connector 3 is accurately attached to the same optical receptacle 11 so that the ferrule 3b attached to the central shaft portion is arranged on the same axis as the ferrule 14 (light conducting portion) connected to the device side optical receptacle 11. Need to be connected.
However, since the device-side optical receptacle 11 is disposed inside the device-side connector insertion portion 10b, it may be difficult to determine the insertion position of the SC connector 3.
Therefore, in the present embodiment, a confirmation window 41 is provided so that the inside of the device-side connector insertion portion 10b can be visually recognized.
Generally, the connector main body 3a of the SC connector 3 is formed with a connection confirmation mark 3c at a predetermined position (see FIGS. 7A and 7B). By arranging the mark 3c at a predetermined relative position with respect to the device-side optical receptacle 11, it is defined that an appropriate connection state of the SC connector 3 is ensured.
In the optical outlet according to the present embodiment, the mark 3 c can be confirmed through the confirmation window 41. Using the confirmation window 41, for example, the upper edge of the confirmation window 41 can be set as a position that ensures an appropriate connection state. That is, the SC connector 3 may be configured to be properly connected to the device-side optical receptacle 11 when the mark 3c is inserted above the upper edge of the confirmation window 41 and becomes invisible from the confirmation window 41.
Further, as shown in enlarged views in FIGS. 6A and 6B, the guide groove 11b for properly mounting the SC connector 3 in the device side optical receptacle 11 disposed inside the device side connector insertion portion 10b. Is formed, and the projection 3d formed on the SC connector 3 is fitted to the guide groove 11b.
The guide groove 11b is preferably made visible through the confirmation window 41. If comprised in this way, it will become easy to match | combine the protrusion 3d with this guide groove 11b, and the suitable mounting operation | work of SC connector 3 can be performed now.
Next, as shown in FIG. 8, the optical outlet of the present embodiment includes a protective bushing 50 that can be inserted into and removed from the device-side connector insertion portion 10b. 9A to 9F, the protective bushing 50 has a configuration in which a knob portion 51a extends from the bushing main body 51 and an elastic sealing portion 52 is provided on the outer periphery of the bushing main body 51 so as to protrude. Yes. Here, the bushing main body 51 and the knob portion 51a are integrally formed of a thermoplastic resin, and the sealing portion 52 is formed of an elastic member such as rubber or a thermoplastic elastomer and is fitted on the outer periphery of the bushing main body 51.
In addition, a sleeve 11a made of a metal tube is generally built in the device-side optical receptacle 11, and a ferrule 14 (light conducting portion) is held by the sleeve 11a (see FIG. 8). The distal end portion 51b of the bushing main body 51 has a shape that fits into the sleeve 11a of the device-side optical receptacle 11 when inserted into the device-side connector insertion portion 10b.
The dimension and shape of the sealing part 52 are set so as to be in close contact with the inner wall of the device-side connector insertion part 10b without a gap. Furthermore, the knob portion 51a is set to a dimension that is exposed downward from the opening of the device-side connector insertion portion 10b in a state where the protective bushing 50 is attached to the device-side connector insertion portion 10b.
When the SC connector 3 is not connected to the device-side optical receptacle 11, the protective bushing 50 closes the opening of the device-side connector insertion portion 10b, thereby preventing dust from entering the inside. When the protective bushing 50 is removed from the device-side connector insertion portion 10b, the knob portion 51a exposed from the opening may be pinched and pulled out.
Further, in the optical outlet of the present embodiment, the protective cover 60 is detachable on the front side of the body 10 and below the opening of the device-side connector insertion portion 10b (see FIGS. 10A and 10B). .
The protective cover 60 has a bent shape as shown in FIGS. 10C and 10D and is attached to the body 10 with a fastener 61 such as a screw. As shown in FIG. 10A, the protective cover 60 has a function of covering the knob portion 51a of the protective bushing 50 attached to the device-side connector insertion portion 10b (exposed from the opening of the device-side connector insertion portion 10b). Have.
This protective cover 60 eliminates the possibility of anything coming into contact with the knob portion 51a of the protective bushing 50 exposed from the opening, so that the mounting state of the protective bushing 50 can be maintained for a long period of time.
Further, when the SC connector 3 is inserted into the device-side connector insertion portion 11b, the protective cover 60 is connected to the device-side connector insertion portion 10b in the connector main body 3a as shown in FIG. The part exposed from the opening is covered. Therefore, unintentional dropping of the SC connector 3 can be prevented.
In general, the device-side optical receptacle 11 to which the SC connector 3 has not been connected for a long time needs to be connected to the SC connector 3 after cleaning the end face of the ferrule 14 (light conducting portion) with a cleaner. Therefore, in the present embodiment, as shown in FIG. 11, a detachable cleaning adapter 70 is provided in the device-side connector insertion portion 10b.
As shown in FIGS. 12A to 12F, the cleaning adapter 70 has a fitting portion 71 to the sleeve 11a at the tip, and a mounting portion 72 to the device-side connector insertion portion 10b at the middle, from the base end. A knob 73 is extended. A through hole 74 is formed in the central shaft portion of the cleaning adapter 70.
In the cleaning adapter 70 having such a configuration, when the mounting portion 72 is fitted into the inner peripheral surface of the device-side connector insertion portion 10b, the fitting portion 71 at the tip is fitted to the sleeve 11a of the device-side optical receptacle 11. To do. At this time, the through hole 74 is positioned on the same straight line as the ferrule 14.
The through hole 74 has an inner diameter through which a stick-shaped cleaner 75 dedicated to an optical connector can be inserted, and the cleaner 75 can be brought into contact with the end face of the ferrule 14 through the through hole. Therefore, since the cleaner 75 can be guided to the end face of the ferrule 14 using the through hole 74 as a guide passage, the cleaning of the ferrule 14 can be easily performed.
The knob portion 73 is set to a size that is exposed from the opening of the device-side connector insertion portion 10b. Therefore, after the cleaning is completed, the cleaning adapter 70 can be easily removed by grasping the knob portion 73 and pulling it out.
[Sixth Embodiment]
13 and 14 are views showing an optical outlet according to the sixth embodiment of the present invention. In these figures, the same or corresponding parts as those shown in FIGS. 5 to 12 are given the same reference numerals.
Similarly to the fifth embodiment, the optical outlet according to the present embodiment also includes a protective bushing 50 that can be inserted into and removed from the device-side connector insertion portion 10b. The protective bushing 50 is configured as shown in FIGS. 9A to 9F.
Furthermore, in the present embodiment, a plate-like protection member 80 that can be freely moved in and out of the opening of the device-side connector insertion portion 10b is provided. The protection member 80 is movable in the front-rear direction along a guide formed on the inner bottom portion of the body 10, and the base end is biased by a biasing member 81 such as a coil spring. The protection member 80 protrudes to a position facing the opening of the device-side connector insertion portion 10b by the urging force of the urging member 81.
On the other hand, a latch mechanism 82 is incorporated between the inner wall of the body along the guide and the base end portion of the protection member. When the protective member 80 is pushed into the body, the latch mechanism 82 locks the protective member 80 at a position slightly moved forward from the pushed position (see FIG. 14). In this state, the protection member 80 is retracted from a position facing the opening of the device-side connector insertion portion 10b.
When the protective member 80 locked at the pushing position is pushed into the body 10 again, the latched state by the latch mechanism 82 is released, and the protective member 80 protrudes with the urging force of the urging member 81, and the device side connector It arrange | positions to the position facing the opening part of the insertion part 10b.
As the latch mechanism 82 having such a function, for example, a latch device disclosed in Japanese Utility Model Laid-Open No. 63-165076 can be applied.
As shown in FIG. 13, the protective member 80 supports the lower end of the protective bushing 50 attached to the device-side connector insertion portion 10 b and prevents the bushing 50 from coming off. When the protective bushing 50 is removed from the device-side connector insertion portion 10b, the protective member 80 is pushed in. In this pushed-in state, the protective bushing 50 can be removed and the SC connector can be inserted into the device-side connector insertion portion 10b.
[Seventh Embodiment]
FIG. 14 is a diagram showing an optical outlet according to the seventh embodiment of the present invention. In these drawings, the same or corresponding parts as those shown in FIG. 1C are denoted by the same reference numerals.
In the optical outlet according to the present embodiment, a splitter (optical branching device) 90 is provided at an intermediate portion between the device-side optical receptacle 11 and the trunk-side optical receptacle 12. As is well known, the splitter has a function of distributing the optical signal transmitted by the optical fiber into a plurality of parts. That is, an optical signal transmitted through one optical fiber can be distributed and transmitted to a plurality of optical fibers by a splitter.
Here, a conventional optical signal distribution structure in FTTH will be described together with its technical background.
In recent years, a multiplex service that allows simultaneous use of not only conventional high-speed Internet connection services but also multi-channel video distribution, fixed-line telephones, FAX communication, etc., is being developed using the same optical fiber line. is there.
In FTTH, an optical fiber cable extending from an optical fiber accommodation facility of an FTTH operator is drawn into a user's house, connected to a line terminator called a media converter or ONU, etc., and converted from an optical signal to an electrical signal. It is configured to connect to a telephone, a television receiver or the like.
In general, a line terminator or the like is provided for each type of transmission signal. A line terminator (ONU) for Internet connection and telephone / FAX (so-called POTS), a line terminator for video transmission ( V-ONU), etc., and it is necessary to install each one corresponding to the service that the user wants to receive.
Therefore, when installing a plurality of line terminators in a dwelling unit, it is necessary to distribute a signal from one optical fiber line and connect it to each line terminator.
Conventionally, a line terminator and the like are collectively stored together with a splitter (optical branching unit) and a WMD (optical branching unit) in a cabinet called an “information distribution board” or the like provided in a dwelling unit. Then, an optical fiber cable is drawn into the cabinet to distribute and demultiplex an optical signal, convert an optical signal to an electrical signal, and send the required signal to each room in the dwelling unit in the form of an electrical signal. The configuration was taken.
As described above, since the splitter and WMD are housed in the cabinet together with the line terminator and the like, the extension of the line terminator and the like that need to be updated in response to the speed increase of the optical communication service or the additional change of the provided service, Replacement is difficult. Therefore, there has been a problem that it is not possible to flexibly cope with future improvements in optical communication services.
On the other hand, according to the configuration of the present embodiment described above, since the splitter is built in the optical outlet installed in each room in the residence, the line termination is performed according to the type of optical communication service that the user uses in each room. Prepare a device and connect it to an optical outlet. When it is necessary to update the line termination device in response to an increase in the speed of the optical communication service or an additional change in the provided service, the device can be easily updated by simply removing it from the optical outlet.
In the optical outlet of the present embodiment, one main line side optical receptacle 12 and a plurality of device side optical receptacles 11, 11,. The main line side optical receptacle 12 and the splitter 90 are connected by a single relay optical fiber 13a. Further, the plurality of device-side optical receptacles 11 and the splitter 90 are connected by relay optical fibers 13b, 13b,.
The optical signal transmitted from the trunk side optical receptacle 12 is distributed by the splitter 90 and output to the plurality of relay optical fibers 13b, 13b,..., And each of the plurality of equipment side optical receptacles 11, 11,. Is transmitted to.
On the other hand, the optical signals input to the device-side optical receptacles 11, 11,... Are mixed by the splitter 90 and transmitted to the trunk-side receptacle 12 via the relay optical fiber 13a.
It is also possible to replace the splitter with a WDM (branching filter). The WDM has a function of demultiplexing a multiplexed optical signal transmitted through an optical fiber according to its wavelength.
In this case, the multiplexed optical signals transmitted from the trunk side optical receptacle 12 are signal-separated according to the wavelength by WDM, and a plurality of transmission types having different transmission types via the plurality of relay optical fibers 13b, 13b. Are transmitted to the device side optical receptacles 11, 11.
On the other hand, the optical signals input to the device-side optical receptacles 11, 11,... Are combined by WDM and transmitted to the trunk-side receptacle 12 via the relay optical fiber 13a.
As an application example of the optical outlet according to the present embodiment, in addition to the splitter and the WDM, the O / E converters 31 and 32 shown in the fourth embodiment can be incorporated.
Note that the optical outlets according to the fifth and sixth embodiments described above can be configured as follows, omitting the trunk side optical receptacle 12. In the future, when the technology of the optical fiber drawn to the main line side is improved and a highly flexible optical fiber is mounted, as shown in FIG. 16, the SC connector 5 of the main line side optical fiber 4 is directly connected to the equipment side optical leasing pull. 11 can also be connected.
(1) In an optical outlet in which a connector insertion portion having a lower surface opened on the front side of the body is formed, and a device-side optical receptacle to which a device-connecting optical connector is connected is disposed in the connector insertion portion.
An optical outlet configured such that a shutter extending downward from the device-side optical receptacle is provided inside the connector insertion portion, and a light beam emitted from the device-side optical receptacle is blocked by the shutter.
(2) The optical outlet according to (1), wherein the shutter is made of a shape memory alloy and is restored to a position where the light beam emitted from the device-side optical receptacle is blocked at room temperature.
(3) The device-connecting optical connector to be inserted into the connector insertion portion has a resin connector body,
The optical outlet according to (1), wherein the shutter is configured to bend in contact with a connector main body inserted into the connector insertion portion.
(4) In an optical outlet formed by forming a connector insertion portion having an open bottom surface on the front side of the body, and arranging a device-side optical receptacle to which a device-connecting optical connector is connected in the connector insertion portion,
The optical outlet which provided the confirmation window which can visually recognize the optical connector for apparatus connection inserted in the connector insertion part in the front wall part of the said connector insertion part.
(5) In an optical outlet in which a connector insertion portion having a lower surface opened on the front side of the body is formed, and a device-side optical receptacle to which a device-connecting optical connector is connected is disposed in the connector insertion portion.
An optical outlet provided with a protective bushing that can be inserted into and removed from the opening in the connector insertion portion.
(6) The protective bushing includes a bushing body and a knob portion extending from the bushing body,
The optical outlet according to (5), wherein the knob portion is exposed downward from an opening of the connector insertion portion when the protective bushing is attached to the connector insertion portion.
(7) The protective bushing is formed by integrally forming the bushing main body and the knob portion with a thermoplastic resin, and elastically close to the inner wall of the connector insertion portion on the outer periphery of the bushing main body. The optical outlet according to the above (6), which is provided with a sealed portion made of an elastic member.
(8) A protective cover that is detachable from the opening of the connector insertion portion on the front side of the body to a lower position and covers the knob portion of the protective bushing exposed from the opening is provided. The optical outlet of (6) above.
(9) In the optical outlet of (8) above, an optical connector for connecting a device having a resin connector body is inserted from the connector insertion portion.
The protective cover is an optical outlet configured to cover the connector main body exposed from the opening of the connector insertion portion in a state in which the device connecting optical connector is inserted into the connector insertion portion.
(10) In an optical outlet in which a connector insertion portion having a lower surface opened on the front side of the body is formed, and a device-side optical receptacle to which an optical connector for device connection is connected is disposed in the connector insertion portion.
A detachable cleaning adapter is provided in the connector insertion part,
The cleaning adapter has a through hole that is attached to the connector insertion portion and is positioned on the same straight line as the optical conducting portion of the device-side optical receptacle. The through hole has a stick-shaped cleaner. An optical outlet that can be inserted from the outside.
(11) In an optical outlet in which a connector insertion portion having a lower surface opened on the front side of the body is formed, and a device-side optical receptacle to which a device-connecting optical connector is connected is disposed in the connector insertion portion.
In the optical outlet according to claim 1, wherein a connector insertion portion having a lower surface is formed on the front side of the body, and the device-side optical receptacle is disposed in the connector insertion portion.
An optical outlet provided with a protective member that can be moved in and out at a position facing the opening of the connector insertion portion.
(12) The optical outlet according to (11), further comprising a latch mechanism that locks the protective member while being pushed into the body.
(13) The connector insertion portion includes a protective bushing that can be inserted and removed from the opening,
The optical outlet according to (11), wherein the protective member is configured to support the protective bushing inserted into the connector insertion portion from below and prevent the protective bushing from coming off from the connector insertion portion.

  As described above, according to the present invention, since the device side optical receptacle and the trunk side optical receptacle are separated and independent, the main line is not restricted by the connection angle of the optical fiber to the device side optical receptacle. It is possible to arbitrarily set the connection angle of the optical connector for main line connection by the side optical receptacle. Therefore, it is possible to freely design the trunk-side optical fiber extending from the trunk-connecting optical connector so as not to be bent suddenly in the wall, and it can also be applied to the connection of a silica-based optical fiber used for FTTH.

Claims (18)

A body having a hollow portion inside and attached to the wall surface of the room via the wiring device mounting frame;
A device-side optical receptacle provided inside the front side of the body and connected to a device-connecting optical connector from the indoor side;
Provided on the back side inside the body, a trunk-side optical receptacle mains connection optical connector extending the trunk optical fiber inside walls are connected,
A signal transmission means for transmitting a signal between the device-side optical receptacle and the trunk-side optical receptacle,
Use an optical receptacle that is compatible with the SC connector for the device side optical receptacle and the trunk side optical receptacle.
For the signal transmission means, an optical fiber core or an optical fiber is used,
The light having an internal space in which the optical fiber core wire or the optical fiber as the signal transmission means connected to the device-side optical receptacle and the trunk-side optical receptacle, respectively, can be curved and stored. Outlet. The optical outlet according to claim 1, wherein a connector insertion portion having an open bottom surface is formed on the front side of the body, and the device-side optical receptacle is disposed in the connector insertion portion.
A shutter that extends below the device-side optical receptacle is provided inside the connector insertion portion, and the light beam emitted from the device-side optical receptacle is blocked by the shutter when the connector is detached. A light outlet. The optical outlet according to claim 2 , wherein the shutter is made of a shape memory alloy or an alloy such as stainless steel having high spring characteristics, and is restored to a position where the light beam emitted from the device-side optical receptacle is blocked at room temperature. The optical connector for device connection inserted into the connector insertion part has a connector body made of resin,
The optical outlet according to claim 2 , wherein the shutter is configured to be bent in contact with a connector main body inserted into the connector insertion portion. The optical outlet according to claim 1, wherein a connector insertion portion having an open bottom surface is formed on the front side of the body, and the device-side optical receptacle is disposed in the connector insertion portion.
The optical outlet which provided the confirmation window which can visually recognize the optical connector for apparatus connection inserted in the connector insertion part in the front wall part of the said connector insertion part. The optical outlet according to claim 1, wherein a connector insertion portion having an open bottom surface is formed on the front side of the body, and the device-side optical receptacle is disposed in the connector insertion portion.
An optical outlet provided with a protective bushing that can be inserted into and removed from the opening in the connector insertion portion. The protective bushing has a bushing body and a knob portion extending from the bushing body,
7. The optical outlet according to claim 6 , wherein the knob portion is configured to be exposed downward from an opening of the connector insertion portion when the protective bushing is attached to the connector insertion portion. The protective bushing is formed by integrally forming the bushing main body and the knob portion with a thermoplastic resin, and elastically close to the inner wall of the connector insertion portion on the outer periphery of the bushing main body, such as rubber or thermoplastic elastomer. The optical outlet according to claim 7 , wherein a sealing portion is provided. The optical outlet according to claim 7 , further comprising a protective cover that is detachably attached to a lower position from the opening of the connector insertion portion on the front side of the body and covers a knob portion of the protective bushing exposed from the opening. In the optical outlet of Claim 9 , the optical connector for apparatus connection which has a resin-made connector main body is inserted from the said connector insertion part,
The protective cover is an optical outlet configured to cover the connector main body exposed from the opening of the connector insertion portion in a state in which the device connecting optical connector is inserted into the connector insertion portion. The optical outlet according to claim 1, wherein a connector insertion portion having an open bottom surface is formed on the front side of the body, and the device-side optical receptacle is disposed in the connector insertion portion.
A detachable cleaning adapter is provided in the connector insertion part,
The cleaning adapter has a through hole that is attached to the connector insertion portion and is positioned on the same straight line as the optical conducting portion of the device-side optical receptacle. The through hole has a stick-shaped cleaner. The optical outlet according to claim 1, wherein the optical outlet is configured to be inserted from the outside. The optical outlet according to claim 1, wherein a connector insertion portion having an open bottom surface is formed on the front side of the body, and the device-side optical receptacle is disposed in the connector insertion portion.
An optical outlet provided with a protective member that can be moved in and out at a position facing the opening of the connector insertion portion. The optical outlet according to claim 12 , further comprising a latch mechanism that locks the protective member while being pushed into the body. The connector insertion portion is provided with a protective bushing that can be inserted and removed from the opening,
The optical outlet according to claim 12 , wherein the protective member is configured to support the protective bushing inserted into the connector insertion portion from below and prevent the connector from coming off from the connector insertion portion. With a plurality of the above-mentioned equipment side optical receptacles,
Inside the body, it has means capable of distributing and mixing signals between the device side optical receptacle and the trunk side optical receptacle,
The optical signal input from the main line side optical receptacle is distributed and output to a plurality of apparatus side optical receptacles, and the plurality of optical signals input from the plurality of apparatus side optical connectors are mixed to the main line side optical connector. The optical outlet according to claim 1, wherein the optical outlet is configured to output. 16. The optical outlet according to claim 15 , wherein a splitter is used as means for distributing and mixing signals between the equipment side optical receptacle and the main line side optical receptacle. With a plurality of the above-mentioned equipment side optical receptacles,
Inside the body, there is means capable of demultiplexing and multiplexing signals between the device side optical receptacle and the main line side optical receptacle,
Multiplexed optical signals input from the main line side optical receptacle are separated and output to a plurality of device side optical receptacles having different transmission types, and a plurality of optical signals input from the plurality of device side optical connectors are output. The optical outlet according to claim 1, wherein the optical outlet is configured to be synthesized and output to the trunk side optical connector. 18. The optical outlet according to claim 17 , wherein a WDM filter is used as means for demultiplexing and multiplexing signals between the device side optical receptacle and the main line side optical receptacle.

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