CN112799173A - Optical fiber beam combining and splitting device - Google Patents

Abstract

The invention relates to an optical fiber beam combiner and splitter, which belongs to the technical field of lasers and adopts

A structure of a mold which will be effective in application

Laser light in root input fiber is synthesized and distributed to

Root output fiber, equivalent to use

An

The optical fiber beam combiner with the structure of the model is provided with a beam splitter,

in order to input the number of optical fibers,

for outputting the quantity of optical fibers, the optical structure is an integrated structure, and the full use of

The outer ring of the cross section of the optical fiber bundle consisting of the input optical fibers can contain more optical fibers than the inner ring, so that the optical fiber bundle can contain more optical fibers than the inner ring

The optical fiber beam combiner with the structure has the advantages that the equivalent tapering ratio of the optical fibers is reduced, the number of optical devices in the laser is reduced, the layout, the wiring and the integration of the laser are simplified, the miniaturization and the light weight of the laser are facilitated, and meanwhile, the optical fiber beam combiner with the structure adopts

The tapered structure can reduce the tapering proportion of the optical fiber, effectively improve the synthesis efficiency, reduce the heat load and inhibit the temperature rise rate.

Description

Optical fiber beam combining and splitting device

Technical Field

The invention belongs to the technical field of lasers, and particularly relates to an optical fiber beam combining and splitting device.

Background

Fiber lasers commonly employ laser diodes as pump sources. In order to increase the laser power, a pump beam combiner is generally used to combine and inject pump light emitted from a plurality of laser diodes into a gain fiber of a fiber laser. Such a pump beam combiner for a fully-fibrillated laserNamely a fiber-pumped beam combiner (US 2018/0102623 a 1), which

The structure of the optical fiber amplifier is characterized in that the optical fiber amplifier has N pumping optical fiber inputs and 1 optical fiber output, and can directly superpose pumping light in at most N pumping sources into the same optical fiber, as shown in figure 1. The optical fiber combiner is an optical fiber device prepared on the basis of a fused biconical taper optical fiber bundle, a bundle of optical fibers are stripped of a coating layer and then arranged together in a certain mode, the optical fibers are heated at high temperature to be fused, meanwhile, the optical fiber bundle is stretched, and an optical fiber heating area is fused to form the fused biconical taper optical fiber bundle, for example, the application number is CN201811150456.0, namely, the optical fiber combiner preparation method and the optical fiber combiner.

For the fiber laser with MOPA configuration and the fiber laser with reverse pump or bidirectional pump, the pumping beam combiner is required to be capable of superposing pumping sources and directly transmitting signal laser, and the pumping beam combiner is adopted in the situation

The structure of the mould is as follows,

the cross section distribution of N pumping fibers surrounding 1 signal fiber is shown, N pumping light and 1 signal light are integrated into the same optical fiber, and the optical fiber is also generally called

A pump signal buncher as shown in fig. 2. At present, due to

The pumping signal buncher has complex process and most of the structures

And

it is difficult to obtain the value of N of 18 or more. Therefore, to further increase the pump light power, fiber laserThe optical device usually adopts a cascade structure of pump beam combiner and beam buncher, as shown in FIG. 3, by cascading N₂An

The pumping beam combiner can be superposed

A laser diode.

Disclosure of Invention

The inventor repeatedly researches the existing pump beam combiner-beam combiner cascade structure and finds that the pump beam combiner-beam combiner cascade structure has two problems: one is that the number of devices used is large, requiring a total of

The beam combining/bundling device not only increases the complexity of the layout, the wiring and the integration of the fiber laser, but also goes against the development trend of miniaturization and light weight of the fiber laser. Second, the pumping optical fiber has a larger taper ratio, so that the brightness of the pumping light is conserved (

Wherein, in the step (A),

for the numerical aperture of the input laser light,

TR is the tapering ratio of the combining/bundling device, which is the numerical aperture of the output fiber) approaches the critical or difficult to maintain, the pump light loss is high, and the output fiber of the combining/bundling device heats seriously.

In particular, as commonly used in present day lasers for research and industry

Pump combiner cascade

The structure of the pump signal buncher is as follows:

the diameter of the input optical fiber of the beam combiner is 125 μm, the clear aperture of the output optical fiber is 220 μm, the numerical aperture is 0.22, and the tapering ratio of the beam combiner is

. If the laser is connected with the conventional universal hectowatt power laser diode (the numerical aperture of the laser is generally 0.15), the numerical aperture of the laser is changed into the numerical aperture of the laser after passing through the cone of the beam combiner

Exceeds the limit of the numerical aperture of the output optical fiber of the beam combiner, so that the synthesis loss reaches several percent even ten percent,

the pump beam combiner has extremely high thermal load, the output optical fiber generates heat seriously, and even the later-stage cascade connection is influenced

The resultant efficiency of the buncher aggravates the thermal load of the succeeding buncher.

In order to solve the above problems, a fiber combiner/splitter is proposed to greatly reduce the tapering ratio of the optical fiber and the loss.

In order to achieve the purpose, the invention provides the following technical scheme:

an optical fiber beam combiner comprises

The structure is applied to the effect that the laser in P input optical fibers is synthesized and distributed into M output optical fibers, P represents the number of the input optical fibers, M represents the number of the output optical fibers, and the structure is equivalent to M output optical fibers

An optical fiber combiner of a type structure is provided with

A root input optical fiber, M output optical fibers,

representing the number of input fibres, M representing the number of output fibres, P₁To represent

The optical fiber combiner with the structure of the type is used for inputting the number of optical fibers, wherein,

by using

The outer ring of the cross section of the optical fiber bundle composed of the input optical fibers can contain more optical fibers than the inner ring, compared with the optical fiber bundle composed of the input optical fibers

The optical fiber beam combiner with the structure has the advantages that the equivalent tapering ratio of the optical fiber is reduced, and the combining efficiency is improved.

Due to the fact that

The application effect of the structure is that the laser in P input optical fibers is combined (equivalent to beam combination) and then distributed (equivalent to beam splitting) to M output optical fibers, namely

The type structure has the beam combination and beam splitting effects, so the theme name is named as the optical fiber beam combination splitter, and the optical fiber beam combination splitter belongs to a brand new structure.

Further, the input optical fiber is a multimode optical fiber, a single mode optical fiber or a few-mode optical fiber.

Further, the input optical fiber is connected with a laser diode or a fiber laser.

Further, the number M of the output optical fibers is equivalent to

The number of the optical fiber beam combiners with the structure is equal.

Further, P₁The number of the input optical fibers and the number of the output optical fibers of the optical fiber beam combiner/splitter are not necessarily integer.

Further, a post-stage cascade fiber combiner or a fiber buncher of the fiber combining and splitting device, or the fiber combining and splitting device can be directly applied, and laser power is redistributed after beam combining and splitting.

Further, the post-cascaded optical fiber combiner adopts

In the form of structure, P₂Indicating the number of input fibers of a downstream cascaded fiber combiner using

In the form of structure, P₂Indicates the number of input pump fibers of the optical fiber buncher in the subsequent cascade, and

。

further, when the number of the optical fiber beam combiner and splitter is 1, the number of the input optical fibers of the post-stage cascaded optical fiber beam combiner is equal to the number of the output optical fibers of the optical fiber beam combiner and splitter, that is, the number of the input optical fibers of the post-stage cascaded optical fiber beam combiner and splitter is equal to the number of the output optical fibers of the post-stage cascaded optical fiber beam combiner

The number of the input pump fibers of the post-stage cascaded optical fiber buncher is equal to the number of the output optical fibers of the optical fiber beam combining splitter, namely

。

Further, when the number of the optical fiber beam-combining beam splitters is P₃When is not in use, and

the number of input optical fibers of the post-cascaded optical fiber combiner and P₃The total number of output fibers of the individual fiber beam combiners is equal, i.e.

The number of the input pump fibers of the post-stage cascaded optical fiber buncher is equal to the total number of the output optical fibers of the optical fiber beam combining and splitting device, namely

。

The invention has the beneficial effects that:

not only is beneficial to reducing the number of optical devices in the laser and simplifying the layout, wiring and integration of the laser, but also is beneficial to the miniaturization and light weight of the laser, and simultaneously, the adoption of the method

The tapered structure can reduce the tapering proportion of the optical fiber, effectively improve the synthesis efficiency, reduce the heat load and inhibit the temperature rise rate.

Drawings

FIG. 1 is

The structure schematic diagram of the optical fiber pumping beam combiner;

FIG. 2 is

The structure schematic diagram of the pumping signal buncher;

FIG. 3 is a schematic diagram of a pump combiner-buncher cascade;

FIG. 4 is a schematic view of the overall structure of the present invention;

FIG. 5 is a schematic diagram of a fiber combiner splitter cascade fiber bunchers.

In the drawings: 1-input fiber, 2-output fiber.

Detailed Description

In order to make the technical solutions of the present invention better understood, the following description of the technical solutions of the present invention with reference to the accompanying drawings of the present invention is made clearly and completely, and other similar embodiments obtained by a person of ordinary skill in the art without any creative effort based on the embodiments in the present application shall fall within the protection scope of the present application. In addition, directional terms such as "upper", "lower", "left", "right", etc. in the following embodiments are directions with reference to the drawings only, and thus, the directional terms are used for illustrating the present invention and not for limiting the present invention.

The first embodiment is as follows:

as shown in FIG. 4, an optical fiber beam combiner/splitter employs

The structure is applied to the effect that the laser in the P input optical fibers 1 is synthesized and distributed to the M output optical fibers 2, and is equivalent to the integration and combination of a plurality of optical fiber beam combiners, so as to reduce the number of optical devices.

Specifically, the optical fiber beam combiner/splitter is regarded as integrating M optical structures

An optical fiber combiner of a type structure is provided with

Root input optical fiber 1, M output optical fibers 2, by using

The outer ring of the cross section of the optical fiber bundle composed of the input optical fibers can contain more optical fibers than the inner ring, compared with the original optical fiber bundle

The optical fiber beam combiner can greatly reduce the equivalent tapering ratio of the optical fiber, improve the combining efficiency and reduce the loss of an optical device, wherein,

said optical fiber is closedThe beam device is provided with P₁Root input optical fiber, 1 output optical fiber.

In addition, the optical fiber beam combining and splitting device has the functions of beam combining and beam splitting. The input optical fiber 1 is a multimode optical fiber, a single mode optical fiber or a few-mode optical fiber, that is, the optical fiber beam combiner can be a beam combiner for pumping light or a beam combiner for signal light. Correspondingly, the input optical fiber 1 may be connected to a laser diode or a fiber laser. In addition, the rear stage of the optical fiber beam combining and splitting device can be cascaded with the optical fiber beam combining device or the optical fiber buncher, the optical fiber beam combining and splitting device can also be directly applied, and laser power is redistributed after beam combining and splitting.

When the post-stage cascade optical fiber beam combiner or the optical fiber buncher of the optical fiber beam combiner/splitter adopts

In the form of structure, P₂Indicating the number of input fibers of a downstream cascaded fiber combiner using

In the form of structure, P₂Indicates the number of input pump fibers of the optical fiber buncher in the subsequent cascade, and

。

specifically, when the number of the optical fiber beam combiner and splitter is 1, the number of the input optical fibers of the post-stage cascaded optical fiber beam combiner is equal to the number of the output optical fibers of the optical fiber beam combiner and splitter, that is, the number of the input optical fibers of the post-stage cascaded optical fiber beam combiner and splitter is equal to the number of the output optical fibers of the post-stage cascaded optical fiber beam combiner

The number of the input pump fibers of the post-stage cascaded optical fiber buncher is equal to the number of the output optical fibers of the optical fiber beam combining splitter, namely

. When the number of the optical fiber beam-combining beam splitters is P₃When is not in use, and

the number of input optical fibers of the post-cascaded optical fiber combiner and P₃The total number of output fibers of the individual fiber beam combiners is equal, i.e.

The number of the input pump fibers of the post-stage cascaded optical fiber buncher is equal to the total number of the output optical fibers of the optical fiber beam combining and splitting device, namely

。

Example two:

as shown in fig. 5, the same parts of this embodiment as those of the first embodiment are not repeated, except that:

the number of the optical fiber beam combining and splitting devices is 2, the optical fiber beam combining and splitting devices are cascaded at the later stage, and the optical fiber beam combining devices cascaded at the later stage adopt

Configuration, number of input pump fibers of fiber bundler

. The optical fiber beam combining and splitting device integrates M optical fiber beam combining and splitting devices on an optical structure

An optical fiber combiner of a type structure is provided with

A number of input fibers, M output fibers, i.e. the number of output fibers and

the number of the optical fiber beam combiners with the structure is equal. At the same time, P₁Without specific requirement, it may be an integer or a non-integer, i.e. of said optical fibre beam combiner-splittersThe ratio of the number of input fibers to the number of output fibers is not necessarily an integer.

Example three:

commonly used with present lasers for research and industry

Pump combiner cascade

The structure of the pump signal buncher is shown as an example (as shown in FIG. 3), and the optical fiber beam combiner/splitter is regarded as combining 3 optical fibers

Optical fiber combiner (equivalent to pump combiner) formation

And if the optical fiber beam combiner is used as the beam splitter (shown in fig. 4), the structure shown in fig. 3 is changed into the structure shown in fig. 5, and the total number of optical devices is reduced by 4. Meanwhile, compared with fig. 1 and 2, fig. 4 only arranges a circle of input fibers in multiple rows on the cross section of the input fiber 1, that is, the cross section area of the input fiber 1 is slightly larger than that of the prior art, but fig. 4 obviously reduces the total number of optical devices, and at the same time, can also effectively reduce the synthesis loss and the light-induced thermal energy.

Setting up

The beam combiner/splitter likewise uses an input fiber with a diameter of 125 μm, and a core/cladding diameter

The numerical aperture of the output optical fiber is 0.22, the tapering ratio of the beam combining and splitting device is

. If the laser is connected with the conventional hectowatt power laser diode (the numerical aperture of the laser is generally 0.15), the numerical aperture of the laser is changed into the numerical aperture of the laser after passing through the beam combining and splitting device

The numerical aperture of the optical fiber is smaller than that of the output optical fiber, and the synthetic efficiency can be close to 100%. Under the condition, the thermal load of the beam combining and splitting device is very low, and the temperature rise rate of the output optical fiber and even the later-stage cascade optical fiber buncher can be effectively inhibited.

The present invention has been described in detail, and it should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

Claims (4)

1. An optical fiber beam-combining splitter is characterized in that

A shape structure equivalent to

An

An optical fiber combiner of a type structure is provided with

A root input optical fiber,

The output optical fiber is arranged at the root end of the optical fiber,

the number of optical fibers contained in the outer circle of the cross section of the optical fiber bundle consisting of the input optical fibers is more than that of the optical fibers contained in the inner circle, wherein,

the optical fiber combiner is provided with

Root input optical fiber, 1 output optical fiber.

2. An optical fiber beam combiner according to claim 1, wherein the input optical fiber is a multimode optical fiber, a single mode optical fiber or a few mode optical fiber.

3. An optical fiber beam combiner according to claim 2, wherein said input optical fiber is connected to a laser diode or a fiber laser.

4. A beam splitter as claimed in claim 2 or 3, wherein the number of output fibres is such that

With equivalent

The number of the optical fiber beam combiners with the structure is equal.

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