KR100476315B1 - Optical fiber connecting system - Google Patents

Abstract

The present invention relates to an optical fiber connection system, comprising: a connection system for connecting an optical waveguide with one or more channels embedded in an optical backplane substrate, comprising: a plug having the optical path and including an optical connector protruding from the connection; And an insertion hole attached to one side surface of the optical backplane substrate to which an end of the optical waveguide is exposed, and an insertion hole into which the optical connector connection part is inserted, and fixing pins for fixing the plug to be disposed at both sides of the insertion hole. It includes; plate, characterized in that the optical waveguide and the optical path is directly connected by the connection portion is inserted into the insertion hole. According to the present invention, the multi-channel optical waveguide and the optical path embedded in the optical backplane can be stably physically connected directly by a simple contact system, thereby ensuring a stable and low connection loss. In addition, the additional fasteners that use the elastic force to hold the plug securely align and fix the optical waveguide and the optical connector so that they are not affected by environmental factors such as vibration, and the optical connector is easily mounted on the alignment plate. Being detachable facilitates replacement and movement of the light path.

Description

Optical fiber connection system {OPTICAL FIBER CONNECTING SYSTEM}

The present invention relates to an optical fiber connection system in an optical communication system, and more particularly, to an optical fiber optical fiber connection system that enables direct connection between an optical waveguide embedded in an optical backplane and an optical connector to which the optical path is connected.

In recent years, the demand for multi-channel parallel optical transmission and reception is increasing in order to smoothly process signals in a system according to the trend of high speed and large capacity of optical communication and to eliminate bottlenecks of existing electrical wiring. Accordingly, optical backplane technology has been actively studied to form a path through which optical signals can be transmitted by stacking and embedding a multi-channel optical waveguide layer on a printed circuit board, which is an existing electrical wiring system.

Optical backplanes with optical waveguides are currently being used in a limited number of applications, including aviation, but are expected to be widely used for home appliances as well as for telecommunications. In the optical backplane, the number of optical access channels has been studied to more than 10 channels, and it is expected that the number of channels will be further expanded by the demand for high-speed large signal processing.

Since the optical signal transmitted through the multi-channel optical waveguide embedded in the optical backplane must be transmitted to another adjacent system, the connection with the optical path, which is a transmission medium between systems, is essential. In the related art, a method of transferring an optical signal by collecting an optical signal coming out of a free space using a lens, attaching an optical fiber to a flexible film, assembling an optical connector, and connecting the optical connectors to a light path There is a way to implement the connection.

The use of an optical system such as a lens requires an additional connection structure for stably aligning the lens in addition to the optical connector, which not only increases additional costs but also transmits an optical signal while maintaining stable optical characteristics in free space. This requires complex alignment and maintenance methods that respond to changes in the vibration environment, which complicates the overall system. As a result, precise assembly techniques and optical system design techniques are required, making it difficult to reduce the cost of multi-channel optical connections. In order to secure and maintain such additional precision, high production costs are required, and low productivity is one factor that increases the cost of constructing an optical communication system.

In addition, a method of connecting optical fibers by directly attaching a film-type optical fiber to the optical backplane and then connecting the optical fibers through a multichannel optical connector is not an optical waveguide but a connection method between optical fibers only. There is a problem that is difficult to apply to.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a connection system having a simple structure having a stability enabling direct physical contact between an optical waveguide embedded in an optical backplane and an optical fiber constituting an optical path.

The present invention relates to a light beam connection system for connecting between an optical waveguide and one or more optical waveguides and optical paths embedded in an optical backplane substrate, comprising: an optical connector having the optical path and including an optical connector protruding the connection part; ; And an insertion hole attached to one side surface of the optical backplane substrate to which an end of the optical waveguide is exposed, and an insertion hole into which the optical connector connection part is inserted, and fixing pins for fixing the plug to be disposed at both sides of the insertion hole. It includes; plate, characterized in that the optical waveguide and the optical path is directly connected by the connection portion is inserted into the insertion hole.

Preferably, the guide formed on the lower surface of the alignment plate; A fixed lever guided by the guide and having a stepped portion engaged with the flange of the plug; An anchor frame fixed to the alignment plate; And an elastic fixing part having a spring mounted between the fixing lever and the anchor frame to enable elastic mounting of the plug.

It will be described below in detail with reference to the drawings.

1 is a schematic diagram of an optical backplane system equipped with an optical fiber connection system according to the present invention, and FIG. 2 is a view for explaining the structure of the optical backplane substrate and the optical connector. Referring to the drawings, the optical fiber connection system according to the present invention includes a plug including an alignment plate attached to one side of an optical backplane substrate having one or more optical waveguides and an elastic fixing part and an optical connector.

1 shows a rack configuration in which an optical backplane is applied. The optical backplane system 1 includes a mother board 3 having a multi-channel optical waveguide 2 embedded therein, and a mother board. The front surface of the board (3) is provided with a small circuit board (daughter board) 4 coupled in a direction perpendicular to the extending direction of the optical waveguide. The optical waveguide connection between the motherboard 3 and the small circuit board 4 is made by changing the traveling path of the optical signal using a mechanism such as a separate 45 ° mirror to transmit and receive signals. On the small circuit board 4, an optical transmission / reception element 5 is mounted to transmit and receive a signal through the optical waveguide. On one side of the motherboard 3, a multi-channel optical waveguide 2 embedded in the motherboard 3 and an optical path connecting system 7 for connecting the optical path 6 made of parallel optical fibers are provided.

The protruding connecting portion 11 of the optical connector 9 included in the plug 8 penetrates the alignment plate 12 and directly connects to the optical waveguide, thereby enabling direct connection between the optical waveguide 2 and the optical path 6. Done. This configuration enables the optical backplane system 1 to transmit optical signals to the outside of the system.

Referring to FIG. 2, the stacking structure of the optical backplane substrate 10 will be described. The optical backplane substrate 10 has a structure in which a plurality of substrates are stacked, and a channel manufactured by a separate process between the stacked substrates. The optical waveguide layer in which the above optical waveguide 2 is embedded is laminated. The built-in optical waveguide 2 is formed of a multi-channel for processing a large amount of signals, and includes a core layer, which is a passage for transmitting light, and a cladding layer, which prevents light from escaping. The optical waveguide layer in which the optical waveguide 2 is embedded is manufactured integrally through a separate process different from the manufacturing process of the printed circuit board. The optical waveguide core is preferably spaced at predetermined intervals to facilitate the connection with the multichannel optical connector 9, and is designed to have a 250 mu m spacing in this embodiment.

The optical connector 9 has a light path 6 made of a ribbon optical fiber. On the front surface of the optical connector 9, the connection portion 11 protrudes in an iron shape to expose the ends of the optical fibers. In addition, it is preferable that guide pins 23 are further formed on both sides of the protruding connecting portion 11 to facilitate the alignment of the optical connector 9 (see FIG. 5). The connecting portion 11 is inserted into the insertion hole 15 of the alignment plate 12, which will be described below, and through such assembly, direct physical contact between the optical waveguide 2 and the optical path 6 is possible. Since the optical path 6 embedded in the optical connector 9 is directly connected to the core of the optical waveguide 2 without any mechanism, the optical fiber embedded in the optical connector also maintains the same alignment gap as the core of the optical waveguide. In the embodiment it is designed to maintain a 250 μm spacing.

3 shows the configuration and operation of the optical fiber connection system according to the present invention, FIG. 4 shows the structure of the alignment plate of the optical fiber connection system according to the present invention, FIG. 5 the structure of the plug, and FIG. 6 the optical backplane substrate. And the bond of the alignment plate is shown.

Referring to the drawings, the alignment plate 12 is attached and fixed directly to one side of the optical backplane substrate 10 to which the optical waveguide 2 is exposed. Various embodiments are possible for the mounting method of the alignment plate, but the present embodiment uses a mounting method through screwing, which will be described below. An insertion hole 15 into which the optical connector connecting portion 11 is inserted is formed at the center of the long plate-shaped alignment plate 12. A scale 16 is formed around the insertion hole 15 along its outer circumference, and when the alignment plate 12 is fixed, the center of the optical waveguide 2 of the optical backplane substrate 10 and the insertion of the alignment plate are fixed. It serves as a guide to match the center of the ball. That is, when fixing the alignment plate 12, through the graduation 16, the insertion hole 15 into which the optical connector connecting portion 11 is to be inserted and the end of the optical waveguide 2 of the optical backplane substrate 10 coincide with each other. It is fixed after being aligned with the center of the optical waveguide 2. Guide holes 19 for alignment are formed at both sides of the insertion hole 15, and the guide pin 23 of the optical connector 9 is inserted therein. In addition, an alignment pin 20 for aligning with the plug 8 on the outer side of the guide hole 19 on both sides is provided on the upper surface of the alignment plate 12. The alignment is guided by the guide hole 19 and the alignment pin 20 in duplicate, thereby enabling more precise alignment.

In order to attach the alignment plate 12 and the optical backplane substrate 10, laser welding or a fastening method using screws may be used. In this embodiment, the coupling hole 21 is formed in the alignment plate 12 for easy fastening, and a screwing method is used. For screwing, coupling grooves 13 are formed on the side of the optical backplane substrate 10 to extend inward. A coupling hole 21 corresponding to the coupling groove 13 is formed in the upper surface of the alignment plate 12 through the alignment plate 12. When the alignment plate 12 is attached, the coupling hole 21 is linearly aligned with the coupling groove 13, and the fixing screw 14 is inserted and fastened through the coupling hole 21. As shown in the figure, the nut is inserted into the end of the coupling groove 13 for screwing, and not only can be fastened through this, but also a thread is formed directly in the coupling groove 13, or the coupling groove 13 Insert a separate coupling auxiliary member formed with a screw line, it can be coupled through. In addition, the coupling pin is formed in the optical backplane substrate 10 may be fixed through a method of inserting and fixing.

As disclosed in FIG. 4, guides for guiding the movement of the fixing lever 17 are formed at both sides of the lower surface of the alignment plate 12. Through this guide formation, the cross section of the guide formed portion in the alignment plate 12 forms an iron shape (22).

The plug 8 in which the optical connector 9 is included is formed in two housings, upper and lower. One housing includes flanges 27 having alignment grooves 26 through which alignment pins 20 formed on the alignment plate 12 pass. In each housing, a mounting groove 24 is formed on which the optical connector 9 is to be seated, and when the optical connector 9 is seated in the mounting groove 24, the upper and lower housings face each other and are assembled by screwing 25. do.

FIG. 7 discloses the structure and function of the elastic fixing portion for elastically fixing the plug 8 to the alignment plate 12. The elastic fixing part includes a fixing lever 17, an anchor frame 18, and a spring 26.

The fixing lever 17 is guided along the guide formed in the alignment plate 12, so that the lower portion of the fixing lever 17 corresponds to the iron cross-sectional shape 22 in which the guide of the alignment plate 12 is formed. A hollow is formed in which the lower center part is opened, and is assembled in such a manner that the alignment plate 12 is fitted through the hollow. Due to the lower structure of the fixing lever 17, it is possible for the fixing lever 17 to move stably along the guide of the alignment plate 12. A step portion 28 is formed in the plug seating direction of the fixing lever 17, that is, the front surface, so that the flange 27 of the plug 8 is engaged. An inclined surface 29 is formed on the upper surface of the step portion 28, and when the plug 8 is coupled to the alignment plate, the plug 8 is drawn toward the alignment plate, and the edge of the flange 27 is inclined. The fixed lever 17 is pushed to the rear side while abutting with 29). Grooves are formed in the rear surface of the fixed lever 17.

The anchor frame 18 is an angled member, and a through groove is formed in the bottom surface, and is fixed together with the alignment plate by the fixing screw 14. The side wall of the anchor is formed with a groove into which the screw 32 is inserted, which is designed to be larger than the diameter of the screw so that the screw is movable left and right. The screw 32 is inserted through the groove so that the end portion is fixed to the rear surface groove of the fixing lever 17. A spring 26 is disposed between the side wall of the anchor frame 18 and the fixing lever 17. That is, the spring 26 is fitted to the screw, one side is supported by the side wall of the anchor frame 18, the other side is supported by the rear surface of the fixing lever 17. Through this configuration, when the flange 27 edge presses the inclined surface 28 while the plug 8 enters the alignment plate 12 to be coupled to the alignment plate 12, the spring 26 is compressed and the fixed lever ( 17 is pushed back, when the plug 8 is inserted, the alignment pin 20 is inserted through the alignment groove 26 and the connecting portion 11 is fully inserted into the insertion hole 15 of the alignment plate 12, As the fixing lever 17 returns to its original position by the elasticity of the spring 26, the flange 27 is fixed while being bitten by the step 28. By this operation, the plug 8 is completely fixed to the alignment plate 12, thereby providing a reliable optical path connection against environmental factors such as external vibration. In addition, since the plug 8 is fixed by the elastic fixing portion, the attachment and detachment is easy and the separation of the plug 8 for repair replacement or the like becomes easy.

According to the present invention, the multi-channel optical waveguide and the optical path embedded in the optical backplane can be stably physically connected directly by a simple contact system, thereby ensuring a stable and low connection loss. In addition, the additional fasteners that use the elastic force to hold the plug securely align and fix the optical waveguide and the optical connector so that they are not affected by environmental factors such as vibration, and the optical connector is easily mounted on the alignment plate. Being detachable facilitates replacement and movement of the light path.

Such a connection system does not require a separate complicated connection structure such as a lens alignment and a fixing device necessary for a free space alignment method using a lens, thereby making it possible to produce an optical fiber connection system at low cost.

1 is a schematic diagram of an optical backplane system with an optical fiber connection system.

2 is a view showing the structure of the optical backplane substrate and the optical connector.

3 is a view showing the configuration and coupling action of the optical fiber connection system.

4 is a view for explaining the alignment plate according to the present invention.

5 is a view for explaining a plug according to the present invention.

6 is a view for explaining the coupling of the alignment plate in the connection system according to the present invention.

7 is a view for explaining the coupling of the structure and the plug of the elastic fixing part in the connection system according to the present invention.

* Explanation of symbols for main parts of the drawings

2; optical waveguide 6; optical path

7; optical fiber connection system 8; plug

9; optical connector 10; optical backplane substrate

12; alignment plate 15; insertion hole

17; fixed lever 18; anchor frame

16; scale 20; alignment pin

21; engagement hole 26; spring

Claims (4)

In a connection system for connecting optical waveguides and optical paths of one or more channels embedded in an optical backplane substrate, A plug including the optical path and including an optical connector protruding from the connection part; And An alignment plate having an end portion of the optical waveguide attached to one side surface of the optical backplane substrate, the alignment hole having an insertion hole into which the optical connector connection part is inserted and both sides of the insertion hole, and fixing pins for fixing the plug. ;; And the optical waveguide and the optical path are directly connected by inserting the connection portion into the insertion hole. The method of claim 1, The alignment plate is formed on the alignment plate, the optical fiber connection system, characterized in that a scale for guiding the center alignment of the optical waveguide and the insertion space is formed. The method of claim 1, Coupling grooves extending inwardly are formed on side surfaces of the optical backplane substrate, And the coupling plate is formed in the alignment plate to fit the coupling groove. The method of claim 1, A guide formed on the bottom surface of the alignment plate; A fixed lever guided by the guide and having a stepped portion engaged with the flange of the plug; An anchor frame fixed to the alignment plate; And an elastic fixing part having a spring mounted between the fixing lever and the anchor frame to enable elastic mounting of the plug.