JP3367344B2 - Optical connection drawer structure - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical connection drawer structure having a drawer in a part of an electronic device, and is particularly characterized in connection between a circuit provided in the drawer and a circuit on the main body side of the device. Optical connection drawer structure.

[0002]

2. Description of the Related Art In an electronic device rack, many signal cables are used for connecting signal lines. In a complicated electronic device, the number of these cables may be enormous, and there is a problem that the outer shape of the housing of the device becomes large in order to secure a space for the cable. Then, JP-A-62
Japanese Patent Laid-Open No. 290198 discloses an intra-carriage wiring technique in which an optical fiber cable is used to significantly reduce the number of cables.

FIG. 3 shows the structure of the optical connection drawer disclosed in this publication. Case 101 of this device
Inside, a first optical fiber cable 102 is arranged along one side thereof. Further, in the housing 101, a box-shaped drawer external housing 103 with one end cut off is formed.
_1, 103 _2, ... are a plurality spaced above and below and right-left direction so as to match their open end with the front panel of the housing 101 (direction perpendicular to the plane of the drawing) interval, these Drawer external housing 103 ₁ , 103
₂ , ... (In the figure, only the drawer outer casings 103 ₁ and 103 ₂ are shown.) Inside the drawer inner casings 104 ₁ and 104.
₂ , ... are stored freely in the drawer. Case 101
The control interface unit 105 is arranged near the bottom of the inside. Drawer internal housing 104 ₁ , 104 ₂ , ...
A plurality of interface units 106 are accommodated in each of the. This drawer internal housing 104 ₁ , 10
4 ₂ , ... rear surface (drawer external housing 103 ₁ , 10
3 _2, on the surface) opposite the open end of ..., in response to these interfaces 106, an electrical signal electricity to be converted into an optical signal - an optical conversion unit 107 and the optical signal into an electric signal A plurality of photoelectric conversion units 108 for conversion are arranged.

The optical-electrical conversion section 107 for converting the optical signal of these into an electric signal has a second optical fiber 11
1 is connected to one end, and the other end is connected to a corresponding one of the electro-optical conversion units 114 each having an end fixed to the first optical fiber cable 102. Similarly, one end of the second optical fiber 111 is connected to the electric-optical conversion unit 108 for converting an electric signal into an optical signal, and the other end is connected to the first optical fiber cable 102.
Are connected to corresponding ones of the opto-electric converters 115 whose ends are fixed.

In such an optical connection drawer structure, by connecting the second optical fiber cable 111 branched from the first optical fiber cable 102 to the optical-electrical converting section 108, the connection of each signal line is made. First and second
The optical fiber cables 102 and 111 are used. Therefore, the number of cables is significantly reduced as compared with the conventional drawer in which the cables are connected one to one.

[0006]

However, in the conventional structure shown in FIG. 3, the drawer outer casing 103 and the drawer inner casing 104, which are drawers that can be pulled out in the operating state, are provided in the electronic device. Have Since this drawer unit is used by pulling it out as necessary, mechanical deterioration is remarkable as compared with other parts constituting the apparatus. The second optical fiber cable 111 is also bent or stretched as the drawer unit is pulled out. Therefore, there is a problem in that material selection is restricted in order to obtain the optical fiber cable 111 that can endure this for a relatively long period of time. Further, it is necessary to replace the second optical fiber cable 111 periodically for maintenance, which not only takes time and labor but also increases the cost of replacement.

Further, in this conventional optical connection drawer structure,
A state in which the drawer inner casing 104 needs to be long enough not to load the second optical fiber cable 111 in the most pulled-out state, and the drawer inner casing 104 is completely accommodated in the drawer outer casing 103. Therefore, a space is required so that the second optical fiber cable 111 can be smoothly bent. If such a movable space is secured, there is a problem that the space for the cable cannot always be effectively reduced.

Therefore, it is an object of the present invention to use a cable for circuit connection between an electronic device having a drawer type housing containing an electronic circuit and this housing and other parts in the electronic device. It is to provide no optical connection drawer structure.

Another object of the present invention is to secure reliability of a circuit connecting portion between an electronic device having a drawer type housing for accommodating an electronic circuit and the housing and other parts in the electronic device. An object is to provide an optical connection drawer that can simplify maintenance.

Still another object of the present invention is to provide a space required for a circuit connecting portion between an electronic device having a drawer type housing containing an electronic circuit and the housing and other parts in the electronic device. It is to provide an optical connection drawer structure capable of reducing

[0011]

According to a first aspect of the present invention, (a) a first housing and (b) a predetermined circuit are incorporated,
A second casing having a depth shorter than the depth of the first casing by a predetermined length and accommodated in the first casing so as to be freely drawn out in the depth direction in the operating state of the predetermined circuit; (C) In the direction that is paired with the inner surface of the second housing and the surface of the first housing that faces the inner surface, at a position that opposes each other and that is substantially orthogonal to the depth direction. A plurality of sets are arranged at intervals, and electric signals are converted into optical signals of different wavelengths at least between adjacent sets and paired respectively.
After the parallel light by response to the collimator lens, and the optical signal emitting unit for emitting the air toward the position against <br/> direction described above,
Each of the optical signals emitted from this optical signal emitting means
Only the corresponding set of wavelengths is transmitted at the opposite positions described above .
The optical connection drawer structure is provided with an optical signal transmission means including a plurality of sets of optical signal reception means for selectively receiving light using a wavelength filter and converting it into an electric signal.

That is, according to the first aspect of the present invention, a plurality of sets of signal transmission in the space on the back side of the first housing and the second housing housed in the first housing in a retractable manner are carried out by air propagation of the optical signal. By doing so, various inconveniences that occur when connecting this part with a cable are eliminated. The optical signal emitting means is characterized in that at least adjacent pairs of optical signals are converted into optical signals of different wavelengths, collimated by a collimator lens, and then collimated, and then the collimated lenses are respectively emitted into the air. Further, the plurality of sets of optical signal receiving means selectively receive light of the optical signals emitted from the optical signal emitting means by using wavelength filters that transmit only the wavelengths of the corresponding pairs at opposing positions and convert them into electrical signals. It is designed to be converted. Therefore, even if the optical signal emitting units are arranged at a relatively narrow interval in a direction substantially orthogonal to the depth direction, the second housing is provided inside the first housing while the predetermined circuit is operating. Even in the case of pulling out in the depth direction, mixing of optical signals of other systems can be prevented, and stable transmission of each optical signal becomes possible.

According to the second aspect of the invention, the first housing and
And a plurality of sets of second housings, each of which is the first
Is it an optical signal transmission means arranged on the surface of the housing facing this?
Characteristic that they are commonly connected to one common board
I am trying.

As a result, one common substrate and
Common processing of signals in other signal processing parts via the board of
Will be possible.

[0015]

[0016]

[0017]

[0018]

DETAILED DESCRIPTION OF THE INVENTION

[0019]

EXAMPLES The present invention will be described in detail below with reference to examples.

FIG. 1 shows an optical connection drawer structure in an embodiment of the present invention. In the electronic device of this embodiment, a back wiring
One board called a board (BWB) 202 is arranged. Further, in the housing 201, box-shaped drawer external housings 203 ₁ , 203 ₂ , ... With one end cut off are vertically and vertically arranged so that their open ends coincide with the front panel of the housing 201. A plurality of drawers are arranged in the left-right direction (perpendicular to the paper surface) at intervals, and these drawer outer casings 203 ₁ , 203 ₂ , ... (only the drawer outer casings 203 ₁ , 203 ₂ are shown in the figure). Inside the drawer, drawer internal housings 204 ₁ , 204 ₂ , ... Are stored so as to be freely drawn out.

A control interface unit 205 of this electronic device is arranged near the bottom of the housing 201. The drawer internal housings 204 ₁ , 204 ₂ , ..., A circuit unit 206 such as a subscriber circuit unit, these interface units 207, and optical signals sent from the direction of the back wiring board 202 are electric signals. And an optical-electrical converting section 208 for converting the optical signal into a specific wavelength component of the optical signal sent.
08 and an optical wavelength filter 209 for making the light incident on
An optical fiber 210 that connects the electrical conversion unit 208 and the optical wavelength filter 209 is housed. Further, the drawer internal housings 204 ₁ , 204 ₂ , ... Are provided with an electro-optical conversion unit for converting an electric signal into an optical signal as a means for transmitting the signal in the direction of the back wiring board 202. 212, an optical fiber 213 for transmitting the converted optical signal, and a collimator lens 214 for converting the optical signal obtained from the optical fiber 213 into parallel light.
Is also housed. The control interface unit 205
It is a circuit that sends and receives signals to and from a circuit unit 206 such as a subscriber circuit unit via the back wiring board 202.

Drawer external housings 203 ₁ , 203 ₂ , ...
A collimator lens 216 is arranged at a position facing the optical wavelength filter 209, and an optical wavelength filter 217 is arranged at a position facing the collimator lens 214, respectively, on the inner back side of the. In the former case, the optical signal 21 emitted from the collimator lens 216
8 enters the opposing optical wavelength filter 209, and in the latter case, the optical signal 219 emitted from the collimator lens 214 enters the opposing optical wavelength filter 217.

The back wiring board 202 is
It has electrical wiring like a normal printed circuit board. The back wiring board 202 includes an electro-optical conversion unit 221 that converts an electric signal into an optical signal.
And an optical-electrical converter 222 for converting an optical signal into an electric signal are arranged at predetermined positions. Electricity-
Light conversion unit 221 and collimator lens 21 corresponding thereto
An optical fiber 223 for guiding the converted optical signal to the collimator lens 216 is connected between the optical fiber 223 and the optical fiber 6. Similarly, an optical fiber 224 for guiding the optical signal selected by the optical wavelength filter 217 to the optical-electrical conversion unit 222 is connected between the optical-electrical conversion unit 222 and the corresponding optical wavelength filter 217. There is.

In the present embodiment, the two types of electro-optical conversion units 212 and 221 both use lasers for converting electric signals into laser light, but other electro-optical conversion devices such as light emitting diodes are used. It may be a conversion means. The two types of photoelectric conversion units 208 and 222 use photodiodes and phototransistors for converting laser light into electric signals, but other photoelectric conversion units may be used. Of course good things. Optical signal 218, 2
At least 19 adjacent signals change their wavelengths so as not to interfere with each other. The optical wavelength filters 209 and 217 that input and pass these optical signals 218 and 219 are configured by filters that pass only optical signals of wavelengths that should be originally passed and block passage of optical signals of other wavelengths. Has been done.

[0025] In the optical connection drawer structure of this embodiment, for example be or push pull the drawer inside the housing 204 ₁ drawer is outer housing 203 ₁ inside housing, electrical - optical conversion section 221 and the light - electric No cable is arranged between the conversion units 208. Therefore, there is no risk that the cable will bend inside the drawer outer casing 203 ₁ as the drawer inner casing 204 ₁ is pushed in, and that the middle portion of the cable will move due to this bending. Particularly in the case of an optical fiber, if the degree of bending of the fiber becomes extreme, it is not preferable from the viewpoint of durability. In this embodiment, since no cable is used, the drawer internal housing 2
Even if 04 ₁ is pulled out or pushed in, no deterioration occurs in the portion transmitting the optical signal.

Further, in the structure of the present embodiment, even if the drawer internal housing 204 ₁ is pulled out or pushed in,
Since no cable is used in the portion where the moving distance changes, it is not necessary to secure a space for the movement accompanying the bending or the expansion and contraction of the distance. When the conventional using cables especially large amount, since required a considerable space, with the size of only drawer outer housing 203 ₁ this amount can be made small, the drawer external housing 2
03 ₁ interval pull-out direction both when pushed drawer inside the housing 204 ₁ completely against it can be narrowed. As a result, not only the height and width of the housing 201 but also the size of the depth can be reduced, which greatly contributes to downsizing of the electronic device.

First Modification

FIG. 2 shows a first modification of the present invention. In FIG. 2, the same parts as those in the embodiment shown in FIG. 1 are designated by the same reference numerals, and the description thereof will be appropriately omitted.

In this first modified example, the drawer external housing 2 is used.
The electro-optical conversion unit 2 is provided at a predetermined position on the back surface of 03 _1.
21 and the optical-electrical conversion part 222 are attached, and the electrical-optical conversion part 221 and the back wiring board 2 are attached.
02 and between the opto-electric converter 222 and the back wiring board 202.
Connected by. Drawer respective electrical outer housing 203 ₁ - optical conversion unit 221 or optical - A hole is drilled for each of the plate surfaces of the attached position of an electric conversion unit 222 transmitting light, through the holes A collimator lens 216 or a light wavelength filter 217 is attached at a position facing each other.

Similarly, an optical wavelength filter 209 is arranged at a position facing the collimator lens 216 in the drawer internal housing 204 ₁ , and the optical wavelength filter 21 is provided.
A collimator lens 214 is arranged at a position opposed to 7. On the plate surface of the drawer inner housing 204 _{1 where} the optical wavelength filter 209 or the collimator lens 214 is arranged, holes are formed to allow light to pass therethrough, and positions facing each other through these holes are provided. Is the optical-electrical converter 208 or the electrical-optical converter 2
12 are arranged respectively. The interface unit 207 of the circuit unit 206 such as a subscriber circuit unit and the optical-electrical conversion unit 208 or the electric-optical conversion unit 212 are connected by cables 311 and 312. Drawer outer housing 203 ₂ and back wiring board 20
2 and the state of connection between the drawer external housing 203 ₂ and the drawer internal housing 204 ₂ are as follows: connection of drawer external housing 203 ₁ and back wiring board 202 and drawer external housing 203 ₁ of FIG. Drawer internal housing 204
It is similar to the connection state of ₁ .

In the optical connection drawer structure of this modification, the electric signal obtained from the control interface unit 205 passes through the back wiring board 202 and the cable 3
It is input to the electro-optical conversion unit 221 via 01. The electro-optical converter 221 converts this into an optical signal. The converted optical signal 218 is converted into the optical wavelength filter 20 that is arranged to face it.
9 and the optical signals of other wavelengths are removed. Then, the light is incident on the photoelectric converter 208. Then, the converted electric signal is input to the corresponding circuit unit 206 via the cable 311.

On the contrary, the electric signal output from the circuit unit 206 is transmitted via the cable 312 to the electric-optical conversion unit 2.
It is input to 12 and converted into an optical signal. This optical signal is
It is converted into parallel light by the collimator lens 214 and is incident on the optical wavelength filter 217 as an optical signal 219. The optical wavelength filter 217 passes only the optical signal 219 in order to remove the passage of other adjacent optical signals. The optical signal that has passed through the optical wavelength filter 217 is converted into an optical-electrical conversion unit 222.
Is converted into an electric signal by the cable 302 and transmitted from the cable 302 through the back wiring board 202 to the control interface unit 205.

[0033]

In the embodiment, the back wiring
Although the signal is transmitted via the board 202,
Similar to the example shown in FIG. 3, an optical fiber may be used to transmit these signals. In this case, the portion where the electrical signal output from the back wiring board 202 is converted into an optical signal becomes the portion that outputs the optical signal as it is or after being amplified, and the optical signal is converted into an electrical signal and back wiring is performed. The part to be input to the board 202 is a part to input the optical signal as it is or to input the optical signal by changing the amplification factor of the input optical signal.

[0035]

As described above , according to the first aspect of the present invention, since the optical signal directly propagates in the air, it is not necessary to use a cable, and troubles due to cable damage are prevented. In addition, it is not necessary to replace the cable, and it is possible to reduce the cost required for maintenance and to prevent the operation of the electronic device from being stopped during maintenance.

According to the invention of claim 1 , the optical communication
No. emission means have different wavelengths at least between adjacent pairs.
To a parallel light with a collimator lens
After that, they are ejecting into the air toward the opposite positions.
It Therefore, when the predetermined circuit is operating, the second housing
Even if it is pulled out in the depth direction,
Comparison of optical signal emission means in a direction almost orthogonal to the depth direction
Even if they are arranged at narrow intervals, they prevent the mixing of optical signals from other systems.
And stable transmission of each optical signal is possible.
become.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an optical connection drawer structure in an embodiment of the present invention.

FIG. 2 is a schematic configuration diagram showing an optical connection drawer structure in a modified example of the present invention.

FIG. 3 is a schematic configuration diagram showing a conventionally proposed optical connection drawer structure.

[Explanation of symbols]

201 housing 202 back wiring board 203 drawer external housing 204 drawer internal housing 205 Control interface unit 206 circuit unit 209,217 Optical wavelength filter 214,216 Collimator lens 218, 219 Optical signal

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-53-123004 (JP, A) JP-A-58-12451 (JP, A) JP-A-59-175183 (JP, A) JP-A-61- 28240 (JP, A) JP 62-290198 (JP, A) JP 4-11967 (JP, A) JP 4-271194 (JP, A) JP 5-129650 (JP, A) JP-A-6-216857 (JP, A) JP-A-7-7176 (JP, A) JP-A-9-153690 (JP, A) Actually open Sho-54-76678 (JP, U) Actual-open Sho-63-92975 (JP, U) (58) Fields surveyed (Int.Cl. ⁷ , DB name) H02J 17/00 H04B 10/00-10/28 H04Q 1/00-1/16 H05K 7/14

Claims (2)

(57) [Claims] 1. A first housing and a predetermined circuit are built-in, and the depth of the first housing is shorter than the depth of the first housing by a predetermined length, and the first housing is provided with the predetermined circuit in an operating state. A second housing housed inside so as to be freely drawn out in the depth direction, and positions at which the inner-side surface of the second housing and the surface of the first housing that faces the second housing face each other. A plurality of pairs of optical signals that are paired with each other and are spaced apart from each other in a direction substantially orthogonal to the depth direction, convert electrical signals into optical signals of different wavelengths at least between adjacent pairs, and correlate them with each other. /> after the parallel light by the meter lens, toward the position where the facing
Of the optical signal emitted from the optical signal emitting means and the optical signal emitted from the optical signal emitting means, and selectively receives the optical signals emitted from the optical signal emitting means at the facing positions by transmitting only the wavelengths of the corresponding set. An optical connection drawer structure comprising: a plurality of sets of optical signal receiving means for converting into an electric signal and an optical signal transmitting means. 2. A plurality of the first casing and the second casing.
Pairs, each of which corresponds to that of the first housing.
From the optical signal transmission means arranged on the facing surface,
2. The substrate is commonly connected to another substrate.
The optical connection drawer structure described.