KR100403740B1 - Optical fiber array equipment structure - Google Patents

Abstract

According to an aspect of the present invention, an optical fiber alignment device includes: an optical fiber block having at least one V-groove formed at a predetermined interval on a silicon substrate, each of which comprises a linear input unit and an output unit, the input unit and an output unit, and a tapered connection unit integrally formed; A ribbon optical fiber formed by double-bonding optical fibers aligned with the V-groove; And a glass top plate on which the optical fibers are bonded to the top of the aligned optical fiber block, the end of which the optical fiber is inserted is rounded, and wherein the ribbon optical fiber is tapered to overlap the edge of the coated portion of the ribbon. . According to the present invention, the gap between the V-grooves formed in the optical fiber block is 127 µm, which makes it possible to miniaturize the optical fiber block and the planar optical waveguide element, and damages the bare optical fiber by rounding the tapered connection portion of the V-groove and the glass top plate end. And bending can be alleviated.

Description

Structure of Fiber Optic Aligner {OPTICAL FIBER ARRAY EQUIPMENT STRUCTURE}

The present invention relates to an optical fiber alignment device for aligning and coupling a planar lightwave device (PLC) and an optical fiber used in a wavelength division multiplexing / demultiplexing communication system.

In general, in a wavelength division multiplexing (WDM) communication system that transmits a large amount of information, optical signals having different N wavelengths are multiplexed onto one strand of optical fiber and simultaneously transmitted. In order to convert the received optical signal into an electrical signal, the receiving end must separate it into optical signals having respective wavelengths. The receiving end of a wavelength division multiplexed communication system based on a single mode optical fiber mainly uses a known optical waveguide grating (AWG) to separate optical signals having multiple wavelengths. In particular, in recent years, many studies have been conducted on the integration of planar optical waveguide devices for manufacturing optical waveguides on a planar substrate for the purpose of optical signal processing such as optical signal branching, modulation, switching, and signal multiplexing. As a technique required to fabricate such a planar optical waveguide device, a waveguide design, fabrication, and packaging may be mentioned. Here, an optical fiber alignment device that connects an optical signal without loss between the planar optical waveguide device and the optical fiber is applied to the device.

Referring to FIG. 1, a description will be given of an optical fiber alignment device for interconnecting a conventional planar optical waveguide device and an optical fiber. As shown in FIG. 1, the optical fiber alignment device 100, 100a coupled to the planar optical waveguide device 110 includes an optical fiber block 120, 130, a glass top plate 135, 135a, and a ribbon composed of optical fibers. The optical fiber 140 and the optical fiber 141 are provided.

The planar optical waveguide device 110 forms a core formed by depositing several layers of silica or polymer thin films on a silicon or quartz substrate, and wraps it with a clad to form a waveguide, and the core and the clad The optical device is designed to divide and sum the intensity of an optical signal according to the shape of a core by using a difference in refractive index of.

The optical fiber blocks 120 and 130 are composed of an input side optical fiber block 120 and an output side optical fiber block 130, and are blocks for aligning and supporting a single optical fiber 141 or a ribbon optical fiber 140. The optical fibers 141 are arranged in the optical fiber block 130 on the output side, respectively, as shown in FIG. 2.

As shown in Figs. 2 and 3, the conventional optical fiber block 130 is composed of a plurality of V-grooves 132 for aligning the bare optical fibers 141 extending from the ribbon optical fiber 140 in sequence. An optical fiber alignment portion 131 and a stress reduction depth portion 136 are provided. The V-groove 132 extends in the longitudinal direction in which the ribbon optical fiber 140, in particular, each of the bare optical fibers 141 is placed. Subsequently, after the bare optical fibers 141 are aligned with the V-groove 132, the glass upper plate 135 is formed on the surface where the bare optical fibers 141 are aligned, that is, with the thermosetting epoxy resin on the optical fiber alignment portion 131. Fix by using the same adhesive. The stress reduction depth portion 136 minimizes bending of the bare optical fiber 141 which occurs in a direction perpendicular to the upper surface of the silicon substrate due to the difference in thickness between the coated portion of the ribbon optical fiber 140 and the bare optical fiber 141. Is provided for this purpose.

The optical fiber aligning device configured as described above has a spacing between V-grooves of 250 μm, and in the case of an optical fiber aligning device for aligning multicore ribbon optical fibers, the gap between V-grooves of 500 μm in units of 8 or 12 cores is provided. Given.

However, due to the V-groove spacing limitation of the optical fiber alignment device, the spacing between the optical waveguide lattice output stages of the planar optical waveguide elements that are formed opposite to each other is widened, so that the size of the planar optical waveguide elements becomes large and difficult to handle. In addition, since the bending of the optical waveguide formed in the planar optical waveguide device becomes severe, the optical signal is lost. In addition, a device having a larger size than a planar optical waveguide device having a relatively small size has a problem in that a separation rate is more likely to occur when bonding with a counterpart.

In order to solve the above problems, an object of the present invention is to narrow the V-groove spacing of the optical fiber block to reduce the size of the optical fiber block to increase the marketability, provide a high degree of integration, easy to handle and package to provide an optical fiber alignment device. Is in.

Another object of the present invention is to narrow the output terminal spacing of the planar optical waveguide device facing the V-groove spacing of the optical fiber block to smooth the bending of the optical waveguide formed on the planar optical waveguide device, thereby reducing the loss of the optical signal. In providing an alignment device.

1 is a view showing an alignment apparatus for connecting a conventional planar optical waveguide element and an input / output side optical fiber block.

Figure 2 is a perspective view showing a state in which the optical fiber is aligned to the optical fiber block according to an embodiment of the prior art.

Figure 3 is a perspective view showing an optical fiber block according to an embodiment of the prior art.

4 is a view showing an optical fiber alignment device according to an embodiment of the present invention.

5 is a perspective view showing an optical fiber block according to an embodiment of the present invention.

6 is a plan view showing an optical fiber block according to an embodiment of the present invention.

7 is a perspective view showing a glass top plate according to an embodiment of the present invention.

FIG. 8 is a cross-sectional view illustrating a state where a glass upper plate is cut along a line A-A shown in FIG. 7.

9 is a perspective view showing a ribbon optical fiber according to an embodiment of the present invention.

FIG. 10 is a view showing a view of a ribbon optical fiber in a C direction shown in FIG. 9; FIG.

Description of the main parts of the drawing

500: optical fiber alignment device 510: optical fiber block

530: V-groove 600: ribbon optical fiber

610: bare fiber 700: glass top

In order to achieve the above object, the optical fiber alignment device according to the present invention is an optical fiber having a fiber alignment portion that is provided with a V-groove at a 127㎛ interval on the silicon substrate and a stress reduction depth portion extending from the optical fiber alignment portion A ribbon optical fiber composed of a block, optical fibers aligned with the V-groove, and a glass top plate which is bonded and fixed with an adhesive to an upper surface of the optical fiber block in which the optical fibers are aligned, wherein the ribbon optical fiber has an end portion of a coating portion of a ribbon. The tapered process is characterized in that the overlapping double.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

5 to 8, the optical fiber alignment device 500 according to the present invention includes an optical fiber alignment portion 520 including V-grooves 530 on which a bare optical fiber 610 is aligned on a silicon substrate. A ribbon optical fiber including a fiber optical block 510 including a stress reduction depth portion 560 extending from the optical fiber alignment portion 520, and a bare optical fiber 610 aligned with the V-groove 530. 600 and a glass upper plate 700 adhered to an upper end of the optical fiber alignment portion 520 in which the bare optical fibers 610 are aligned.

As shown in Figures 4 to 6, the optical fiber block 510 of the optical fiber alignment device 500 according to the present invention is an optical fiber alignment portion 520 consisting of a plurality of V-grooves 530 on a silicon substrate. And a stress reduction depth portion 560 extending from the optical fiber alignment portion 520 in the direction in which the bare optical fiber 610 is inserted and having a step 550 and an upper surface of the optical fiber alignment portion 520. do. The V-grooves 530 formed on the silicon substrate are integrally connected to each other by a linear input part 531 and an output part 533 and a tapered connection part 532 between the input part 531 and the output part 533. The widths of the input unit 531 and the output unit 533 are different from each other. The step 550 between the optical fiber alignment portion 520 and the stress reduction depth portion 560 is a portion of the coating of the ribbon optical fiber 600 when the bare optical fiber 610 is aligned with the V-groove 530. In order to minimize bending of the bare optical fiber generated due to the difference in coating thickness between the bare optical fibers 610, the bending is provided. In the optical fiber alignment device 500, the spacing between the V-grooves 530 of the optical fiber block 510 is 127 µm, so that the spacing between V-grooves is 250 µm or 500 µm. Make the size smaller. In addition, the width of the input portion 531 of the V-groove 530 is wider than the width of the output portion 533 and connected to the tapered connector 532 to connect the bare optical fiber 610 to the V-groove 530. It prevents damage of the bare optical fiber 610 due to friction when inserted into, and prevents sudden bending of the bare optical fiber 610.

9 and 10, the ribbon optical fiber 600 arranges a plurality of bare optical fiber 610 strands aligned with the V-groove 530 of the optical fiber block 500 and overlaps them again in duplicate. It is configured by. By configuring the ribbon optical fiber 600 to be superimposed in duplicate, it has been possible to narrow the gap between the V-grooves of 250 μm or 500 μm to 127 μm. Therefore, by aligning a larger number of optical fibers in the same size of optical fiber blocks, it is possible to reduce the size of the alignment device and improve the integration degree of the planar optical waveguide device opposite thereto. In addition, the ribbon end portion 620 of the ribbon optical fiber 600 is processed inclined, and then overlapping the processed parts to face each other can be bent the bending of the bare optical fiber 610.

As shown in FIGS. 4, 7, and 8, the glass top plate 700 is fixedly coupled to the optical fiber block 510 in which the bare optical fiber 610 is aligned. Specifically, the glass upper plate 700 is adhesively fixed by applying an adhesive, such as a thermosetting resin, to the optical fiber alignment portion 520 of the optical fiber block 510 in which the bare optical fiber 610 is aligned. The glass upper plate 700 may check the alignment of the bare optical fiber 610 using a transparent material. In addition, the glass upper plate 700 rounds (B) the end portion 710 into which the bare optical fiber 610 is inserted to reduce friction, etc., generated when the bare optical fiber is inserted, and prevents abrupt bending of the inserted bare optical fiber. . Both side ends 750 of the glass upper plate 700 are bent and extended, and the extended ends 755 adhere to the optical fiber block 510.

As described above, the optical fiber block of the optical fiber alignment device according to the present invention forms a V-groove at an interval of 127 μm in the optical fiber alignment portion where the bare optical fiber is aligned, thereby miniaturizing the alignment device. Since the inter-waveguide spacing is 127 μm, the degree of integration of the planar optical waveguide device is improved, and the bending of the waveguide formed on the planar optical waveguide device is alleviated, thereby preventing the loss of the optical signal. In addition, the width of the input portion into which the bare optical fiber is inserted into the V-groove is connected to the output through a tapered connection portion, and the rounded end of the bare optical fiber is inserted into the glass upper plate adhesively fixed to the optical fiber alignment portion of the optical fiber block. It was. Therefore, the bare optical fiber is prevented from being damaged by friction when the bare optical fiber is inserted, and the bending of the bare optical fiber is relaxed after the bare optical fiber is inserted. Moreover, the ribbon optical fiber facilitated double overlapping by tapering the ends of the coated portion of the ribbon.

Claims (4)

An optical fiber alignment device for interconnection of planar optical waveguide elements and optical fibers, A fiber alignment portion comprising at least one V-groove each having a linear input portion and an output portion, the input portion and the output portion, and a tapered connection portion integrally formed, and a stress reducing depth portion extending from one end of the optical fiber alignment portion. An optical fiber block; A ribbon optical fiber consisting of optical fibers aligned with the V-groove; And A glass top plate bonded to the top of the optical fiber block in which the optical fibers are aligned; The ribbon optical fiber is an optical fiber alignment device, characterized in that the ends of the coating portion of the ribbon is tapered to overlap the double. The method of claim 1, wherein the glass top plate, Optical fiber alignment device, characterized in that it has a protrusion that is bent at both ends to extend a predetermined length and the extended end is bonded to the optical fiber alignment portion of the optical fiber block. The glass plate of claim 2, Optical fiber alignment device, characterized in that the rounded edge of the end of the optical fiber is inserted. delete