KR20060024735A - Wavelength division multiplexer and its manufacturing method for thin film - Google Patents

Abstract

The present invention relates to a thin-film filter type wavelength reducing device and a manufacturing method thereof, and more particularly, to a thin-film filter type wavelength reducing device, comprising: a two-core pigtail in which a two-core capillary and an optical fiber are assembled; A two-core collimator in which the two-core pigtail and the lens are optically aligned with each other; The two-core collimator is inserted into the glass tube and the glass tube inserted therein, the surface of the gold-plated tube, the thin film filter and the gold-plated filter holder attached to each other with thermosetting epoxy without optical alignment, and It relates to a thin-film filter type wavelength sensitizer characterized in that the two-core collimator and the filter holder is optically aligned and then fixed with solder.

In the case of products using the existing epoxy, it is impossible to align it again after the applied epoxy is cured during the aligning and fixing process, so it is not possible to correct the increase in loss due to the minute movement caused by the difference in curing time between the epoxy surface and the inside of the curing process. According to the invention, the thin-film filter type wavelength sensitizer and the manufacturing step according to the present invention can correct the distorted part by re-arrangement of only a specific part by the iron, etc. in the loss caused by the fine distort caused by solder fixation during the alignment and fixing process. .

In addition, by using a non-epoxy solder to fix the position of the optical alignment, basically the amount of displacement due to the heat of the epoxy is excluded, and mechanical properties such as vibration and shock are also improved.

In particular, the combination by soldering achieves a perfect sealing effect and improves not only the temperature but also the properties of humidity, solvents, and the like. Therefore, in the prior art, the operating temperature is -10 ° C to 65 ° C, and the thin-film filter type regulator according to the present invention can extend to -40 ° C to 100 ° C.

 Furthermore, in the case of conventional epoxy products, when the defect occurs during the alignment and fixing process, it is impossible to safely remove the previously applied epoxy, and thus it is impossible to use the raw material again, but in the case of the product according to the present invention, the alignment and fixing process Even if a bad defect occurs, it can be recycled to raw materials through the solder reprocessing process due to high temperature, thereby completely reducing the case of waste failure.

Thin film, filter, epoxy, solder

Description

Thin-film filter type wavelength sensitizer and its manufacturing method {Wavelength Division Multiplexer and Its Manufacturing Method for Thin Film}

1 is a schematic view showing a thin film filter type wavelength reducing device according to the prior art.

Figure 2 is a schematic diagram showing a thin film filter type wavelength reducing device according to the present invention.

 <Explanation of symbols on main parts of the drawings>

1: input fiber

3: tube 4: glass tube

5: 2-core capillary 6: lens

7: thin film filter 8: epoxy

9: filter holder 10: reflective optical fiber

11: solder

The present invention relates to a thin film filter type wavelength reducing element and a method of manufacturing the same, and more particularly, to a thin film filter type wavelength reducing element, a two core pigtail in which a two core capillary and an optical fiber are assembled; A two-core collimator in which the pigtail and the lens are optically aligned with each other; The two-core collimator is inserted into the glass tube and the glass tube inserted therein, the surface of the gold-plated tube, the thin film filter and the gold-plated filter holder attached to each other with thermosetting epoxy without optical alignment, and It relates to a thin-film filter type wavelength sensitizer characterized in that the two-core collimator and the filter holder is optically aligned and then fixed with solder.

In general, the optical cable of the wired communication line is rapidly progressing due to the rapid increase in the wired communication network communication capacity due to the expansion of the Internet and the increase in the connection capacity with the wired communication network due to the increase in the communication capacity of the wireless communication network.

Similar to the multiplexing of signals on a single line using multiple frequencies to expand the capacity of the existing copper line, similarly to the multiplexing of signals using different wavelengths in a single line. It is adopted and commercialized in this one-sided way.

This is a method of transmitting several individual optical signals simultaneously on a single line. If four 2.5 Gbps capacity transmission systems generate optical signals with four different wavelengths, they use a wavelength division multiplexer (WDM). When a single optical fiber is incident on a single optical fiber, the total communication processing capacity is 2.5 * 4 = 10 Gbps. Thus, the same effect can be obtained without introducing a separate 10 Gbps transmission system.

In this way, more than 1Tbps transmission system is commercialized. In addition, PON (Passive Optical Network), which is being commercialized in line with the upcoming FTTH (Fiber To The Home), is expected to have modules installed outdoors, and thus, the operating temperature range of each optical part is required to be expanded.

Meanwhile, due to the increase in the amount of information in wireless communication such as PCS and IMT2000, most base station and repeater connections are already established by optical fiber, and as the continuous use of radio frequency increases, the service area of each repeater is reduced and the number of necessary repeaters is increasing. . This means the need for a new optical line, and in order to improve the efficiency of the optical channel, all optical islands have already used uplink and downlink signals as single lines using light of different wavelengths. Such optical repeaters are also often installed outdoors, and high reliability of optical components used is required.

1 is a schematic view showing a thin film filter type wavelength reducing element according to the prior art, which will be described below. First, the lens 6 and the thin film filter 7 are attached to the epoxy 8 without optical alignment, and thus integrated with the filter. The two-core capillary 5 on which the lens 6, the input optical fiber 1, and the reflective optical fiber 10 are mounted is aligned, and the connection portion is fixed with an epoxy 8.

Multiple wavelengths are input to the input optical fiber 1, and the optical fiber 1 is supported by the two-core capillary 5 and optically aligned with the capillary 5 and the lens 6. It goes straight in parallel without spreading into the air.

The light propagated in parallel is incident on the thin film filter 7 to transmit only light of a specific wavelength, and light of the remaining wavelengths is reflected and is reflected back to the other reflected optical fiber 10 of the two-core capillary 5 through the lens 6. ) Will be incident.

This configuration has relatively stable thermal characteristics because the input optical fiber 1 and the reflected reflective optical fiber 10 simultaneously move even when the epoxy 8 is deformed due to external heat to compensate for displacements.

The assembling process of the prior art according to FIG. 1 is described in detail as follows.

Optically aligning and assembling the two-core capillary (5) and the input and reflective optical fibers (1,10),

Optically aligning and assembling the two-core capillary 5 and the lens 6,

Attaching the epoxy (8),

After the optical alignment and assembly of the two-core capillary (5) and the lens (6) consists of an assembly process comprising the step of scientific alignment and assembly of the thin film filter (7) and attaching the epoxy (8).

A solvent of a specific medium is used to fix the optical material after the alignment of the optical materials in the above process. Usually, the medium has to have excellent thermal properties, and in particular, the thermal expansion coefficient is the most important characteristic.

This is because the characteristics of the device are greatly changed even when the positions of the aligned optical parts move less than 1 micrometer. The general communication system is used indoors and the use temperature environment does not exceed 50 degrees Celsius from minus 10 ℃, while the temperature of the optical element used outdoors can be from minus 40 ℃ to high temperature 85 ℃, so that the thermal characteristics of fixed medium are more. It becomes important.

The most commonly used media are resin epoxy and metal solder. Epoxy is again classified as thermoset and ultraviolet curable epoxy, and solder is mostly lead-based.

Epoxy is easy to use because it is free from fixing materials and irrespective of the material of the object to be used.However, even though it has excellent thermal properties, it is difficult to clarify the condition after long periods of time. In addition, it is not suitable for use except in the case where a closed apparatus can be used due to the change of the characteristics depending on the curing conditions.

On the other hand, although solder has limitations in use such as gold plating of the surface of the counterpart to be fixed, the thermal property is very excellent once fixed.

Therefore, in the WDM of the above structure, the components are circular, such as the assembly of the capillary and the optical fiber and the assembly of the capillary and the lens. This symmetry allows thermal equilibrium.

However, the prior art has the potential problem of leaving the compensable displacement due to high temperature long-term storage or contamination of the epoxy by moisture infiltration.

The present invention has been made to solve the above problems, and the object of the present invention is because of the possibility of change according to the epoxy curing conditions, by using a non-epoxy solder when fixing the alignment between the two-core capillary and the thin film filter, The aim is to increase the production yield by improving the thermal characteristics and adopting a product composition that can be reprocessed.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a schematic view showing a thin film filter type wavelength sensitizer according to the present invention, which will be described in detail as follows.

The present invention is a two-core pigtail assembled with a two-core capillary (5) and pressure and reflective optical fibers (1, 10);

A two-core collimator in which the two-core pigtail and the lens 6 are optically aligned with each other;

A glass tube (4) in which the two-core collimator is inserted;

A tube 3 inserted into the glass tube 4 and surface-treated with gold plating;

The thin film filter 7 and the gold-plated filter holder 8 are mutually attached to each other by thermosetting epoxy without optical alignment, and the two-core collimator and the filter holder 9 are optically aligned and then fixed by solder 11. The present invention relates to a thin film filter type wavelength regulating element.

The solder 11 further fixes other components located therein by attaching the filter holder 9 and the tube 3.

The second core capillary 5 is positioned inside the glass tube 4, and a portion of the lens 6 is positioned.

Referring to the manufacturing steps for this, as follows.

The present invention is in the step of manufacturing a thin film filter type wavelength reducing element,

 A two-core pigtail manufacturing step of assembling the two-core capillary and the input and reflective optical fibers;

 Manufacturing a two-core collimator that optically aligns with the lens after the two-core pigtail manufacturing step, and inserting into the glass tube to fix the alignment of the steps, using a thermosetting epoxy;

Inserting the glass tube into a tube whose outer surface is gold plated;

 A manufacturing step of attaching the gold-plated filter holder and the thin film filter to each other with thermosetting epoxy without optical alignment;

It relates to a method for manufacturing a thin-film filter type wavelength sensing device comprising the step of fixing the two-core collimator and the filter holder with an optical alignment after the solder.

As described above, in the case of the products using the existing epoxy, it is impossible to realign the coated epoxy after curing during alignment and fixation, thereby correcting the increase in loss due to the minute movement caused by the difference in curing time between the epoxy surface and the inside of the curing process. However, according to the present invention, the thin-film filter type wavelength sensitizer and its manufacturing method can correct the misaligned part by re-arrangement of only a specific part by the soldering of the loss caused by the slight misalignment caused by solder fixation during the alignment and fixing process. It is.

In addition, by using a non-epoxy solder to fix the position of the optical alignment, basically the amount of displacement due to the heat of the epoxy is excluded, and mechanical properties such as vibration and shock are also improved.                     

In particular, the bonding by the solder to achieve a perfect sealing effect is improved not only the temperature but also the characteristics of humidity, solvents, and the like. Therefore, in the prior art, the operating temperature is -10 ° C to 65 ° C, and the thin-film filter type regulator according to the present invention can extend to -40 ° C to 100 ° C.

Furthermore, in the case of conventional epoxy products, when the defect occurs during the alignment and fixing process, it is impossible to safely remove the previously applied epoxy, and thus it is impossible to use the raw material again, but in the case of the product according to the present invention, the alignment and fixing process Even if a bad defect occurs, it can be recycled to raw materials through the solder reprocessing process due to high temperature, thereby completely reducing the case of waste failure.

Claims (4)

In the thin film filter type wavelength regulating element, A 2-core pigtail in which the 2-core capillary 5 and the input and reflective optical fibers 1 and 10 are assembled; A two-core collimator in which the two-core pigtail and the lens 6 are optically aligned with each other; A glass tube (4) in which the two-core collimator is inserted; A tube 3 inserted into the glass tube 4 and surface-treated with gold plating; The thin film filter 7 and the gold-plated filter holder 9 are mutually attached to each other by thermosetting epoxy without optical alignment, and the two-core collimator and the filter holder 9 are optically aligned and then fixed by solder 11. Thin film filter type wavelength regulating element, characterized in that. The method of claim 1, The solder (11) is a thin film filter type wavelength regulator, characterized in that for attaching the filter holder (9) and the tube (3). The method of claim 1, The two-core capillary (5) is located inside the glass tube (4), and a thin film filter type wavelength regulating device, characterized in that a portion of the lens (6) is located. In the step of manufacturing a thin film filter type wavelength reducing element, A two-core pigtail manufacturing step of assembling the two-core capillary and the input and reflective optical fibers; Manufacturing a two-core collimator that optically aligns with the lens after the two-core pigtail manufacturing step, and inserting into the glass tube to fix the alignment of the steps, using a thermosetting epoxy; Inserting the glass tube into a tube whose outer surface is gold plated; A manufacturing step of attaching the gold-plated filter holder and the thin film filter to each other with thermosetting epoxy without optical alignment; And optically aligning the two-core collimator and the filter holder, and fixing them with solder.

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