METHOD AND DEVICE FOR PROCESSING ACTIVE MICROCRYSTALLINE FIBER BY MAGNETIC FIELD INDUCTION AND LASERIT

Abstract

The invention discloses a preparation method and device of active microcrystalline fiber, place the prefabricated rod in the drawing furnace for wire drawing, the drawn fiber is induced by magnetic field in uncoated state and combined with laser treatment technology, the laser beam is focused on the fiber and recrystallized after laser treatment to obtain active microcrystalline fiber. Appropriate laser processing power directly affects the silicate glass fiber in the crystal structure, type, degree of crystallinity, grain size, content, and how much residual phase of glass. Induced by external magnetic field, the thermodynamics and dynamics of crystallization process are changed, make the crystal size distribution is better and uniform, reduce the phenomenon of condensation and makes the grain size is smaller.

Claims

1.-14. (canceled)

15. A method of preparation active optical fiber, wherein the drawn fiber is introduced into a magnetic field and the fiber is irradiated by a laser, in place the prefabricated rod in a drawing furnace for wire drawing, the drawn fiber is induced by magnetic field in uncoated state and combined with laser treatment technology, the laser beam is focused on the fiber and recrystallized after laser treatment to obtain active optical fiber.

16. The method of preparation active optical fiber according to claim 1, wherein the magnetic field is a stable magnetic field, alternating magnetic field or pulsed magnetic field.

17. The method of preparation active optical fiber according to claim 1, wherein the strength of the magnetic field is 0-5T.

18. The method of preparation active optical fiber according to claim 1, wherein the laser has a power of 0-5W.

19. The method of preparation active optical fiber according to claim 1, wherein the laser beam spot is ring or circular, and the diameter of the spot is 0.1˜5 mm.

20. An active optical fiber prepared by the method of claim 1, Including a fiber core and a cladding layer, wherein the fiber core is yttrium aluminum garnet, bismuth germanate, lead tungstate or sodium iodide. The crystal size is 2˜100 nm, and the cladding is quartz material.

21. The active optical fiber according to claim 6, wherein the cores are singly or jointly doped with: ytterbium, neodymium, erbium, bismuth, thulium, holmium, cerium, terbium, and gadolinium.

22. The active optical fiber according to claim 6, wherein the diameter of the fiber core is 5˜100 um, and the diameter of the cladding is 120˜800 um.

23. The active optical fiber according to claim 6, wherein the active microcrystalline fiber passes the laser performance test and produces laser output with conversion efficiency of 30˜80%.

24. A device of preparation active optical fiber, including wire drawing furnace (2), wherein a magnetic field generating device (3) and a laser generator (4) are arranged in the outlet direction of wire drawing furnace (2). in place the prefabricated rod in the drawing furnace for wire drawing, the drawn fiber is induced by magnetic field in uncoated state and combined with laser treatment technology, Complete the laser processing of the doped fiber under the action of a magnetic field, the laser beam is focused on the fiber and recrystallized after laser treatment to obtain active optical fiber.

25. The device of preparation active optical fiber according to claim 10, wherein the magnetic field generated by the magnetic field generator (3) is stable magnetic field, alternating magnetic field or pulsed magnetic field.

26. The device of preparation active optical fiber according to claim 10, wherein the laser generator (4) is fiber laser, gas laser or semiconductor laser.

27. The device of preparation active optical fiber according to claim 10, wherein the drawing furnace is a graphite drawing furnace or a laser drawing furnace.

Description

BRIEF DESCRIPTION OF THE DRAWING

[0025] FIG. 1 is a schematic diagram of the preparation device of the invention.

[0026] Including: 1— Prefabricated rod, 2— Wire drawing furnace, 3— Magnetic field generating device, 4— Laser generator, 5— Active microcrystalline fiber.

[0027] FIG. 2 is a schematic diagram of the cross section structure of the active microcrystalline fiber of the invention.

[0028] FIG. 3 is the scanning electron microscope diagram of the active microcrystalline optical fiber core of the invention.

[0029] FIG. 4 is a schematic diagram of the laser output spectrum of the active microcrystalline fiber of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0030] The specific embodiments of the invention are further described in combination with the attached drawings, but the scope of protection required is not limited to this.

[0031] As shown in FIG. 1, a method and device for processing active microcrystalline fiber by magnetic field induction and laserit, the specific steps are: Place the prefabricated rod 1 in the drawing furnace 2 for wire drawing, the drawn fiber passes uncoated through the magnetic field generator 3 and laser generator 4, by introducing magnetic induction and laser processing, the laser beam is focused on the fiber and recrystallized after laser treatment to obtain active microcrystalline fiber 5.

[0032] Drawing furnace 2 is graphite drawing furnace or laser drawing furnace.

[0033] The magnetic field generated by the magnetic field generating device 3 is any of the stable magnetic field, alternating magnetic field and pulsed magnetic field, and the magnetic field intensity is 0˜5T.

[0034] The laser generator 4 uses fiber laser, gas laser, semiconductor laser in any one, laser processing power is 0˜5W.

[0035] The laser beam spot is ring or circular, and the diameter of the spot is 0.1˜5 mm.

[0036] As shown in FIG. 2, the cross section structure of microcrystalline fiber includes fiber core 11 and cladding 22, and fiber core 11 is located at the center of cladding 22.

[0037] The diameter of the fiber core is 5˜100 um, and the diameter of the cladding is 120˜800 um.

[0038] The fiber core 11 is yttrium aluminum garnet, bismuth germanate, lead tungstate or sodium iodide. Active crystal precipitation, the crystal size is 2˜100 nm, and the cladding 22 is quartz material.

[0039] The active crystals include ytterbium, neodymium, erbium, bismuth, thulium, holmium, cerium, terbium, gadolinium, single-doped or co-doped garnet crystals, bismuth germanate crystals, lead tungstate crystals, sodium iodide crystal materials, etc.

[0040] The active microcrystalline fiber passes the laser performance test and produces laser output with conversion efficiency of 30˜80%.

Example 1

[0041] As shown in FIG. 1, a method for processing active microcrystalline fiber by magnetic field induction and laserit, the specific steps are: Yb:YAG crystals with a doping concentration of 10 at % were processed into micron rods, their surfaces were polished, and the rods were inserted into the cleaned and dried quartz sleeve to make prefabricated rods. The prefabricated rod is fixed on the laser drawing furnace by aluminum fixture for wire drawing, in wire drawing; the doped fiber drawn is made to pass through an alternating magnetic field in an uncoated state. The two magnetic poles of the alternating magnetic field are vertically placed on both sides of the fiber, and the fiber coincide with the central axis of the two magnetic poles. The magnetic field intensity is 0.2T, and the carbon dioxide laser is turned on at the same time, laser processing power is 1.5W. The laser beam is focused and shaped into ring spots acting around the fiber, so that the fiber is heated evenly, and the diameter of the spot is 200 um.

[0042] As shown in FIG. 2, the core diameter of active microcrystalline optical fiber is 15˜20 um, the diameter of the cladding is 130˜200 um, and fiber core is located at the center of cladding.

[0043] As shown in FIG. 3, the fiber core is yttrium aluminum silicate material. By scanning electron microscope to observe the fiber core, obviously observed crystal precipitation, he crystal size is 30˜50 nm, and the crystal distribution is relatively uniform.

[0044] As shown in FIG. 4, the active microcrystalline fiber passes the laser performance test and produces laser output with conversion efficiency over 30%.

Example 2

[0045] A method for processing active microcrystalline fiber by magnetic field induction and laserit, the specific steps are: Yb:YAG crystals with a doping concentration of 10 at % were processed into micron rods, their surfaces were polished, and the rods were inserted into the cleaned and dried quartz sleeve to make prefabricated rods. The prefabricated rod is fixed on the laser drawing furnace by aluminum fixture for wire drawing, in wire drawing; the doped fiber drawn is made to pass through an alternating magnetic field in an uncoated state. The two magnetic poles of the alternating magnetic field are vertically placed on both sides of the fiber, and the fiber coincide with the central axis of the two magnetic poles. The magnetic field intensity is 0.1T, and the carbon dioxide laser is turned on at the same time, laser processing power is 2W. The laser beam is focused and shaped into ring spots acting around the fiber, so that the fiber is heated evenly, and the diameter of the spot is 200 um.

[0046] The core diameter of active microcrystalline optical fiber is 6˜12 um, the diameter of the cladding is 120˜150 um, and fiber core is located at the center of cladding.

[0047] The fiber core is yttrium aluminum silicate material. By scanning electron microscope to observe the fiber core, obviously observed crystal precipitation, he crystal size is 40˜60 nm, and the crystal distribution is relatively uniform.

[0048] The active microcrystalline fiber passes the laser performance test and produces laser output with conversion efficiency over 30%.

Example 3

[0049] A method for processing active microcrystalline fiber by magnetic field induction and laserit, the specific steps are: Yb:YAG crystals with a doping concentration of 10 at % were processed into micron rods, their surfaces were polished, and the rods were inserted into the cleaned and dried quartz sleeve to make prefabricated rods. The prefabricated rod is fixed on the laser drawing furnace by aluminum fixture for wire drawing, in wire drawing; the doped fiber drawn is made to pass through an alternating magnetic field in an uncoated state. The two magnetic poles of the alternating magnetic field are vertically placed on both sides of the fiber, and the fiber coincide with the central axis of the two magnetic poles. The magnetic field intensity is 0.5T, and the carbon dioxide laser is turned on at the same time, laser processing power is 3W. The laser beam is focused and shaped into ring spots acting around the fiber, so that the fiber is heated evenly, and the diameter of the spot is 500 um.

[0050] The core diameter of active microcrystalline optical fiber is 20˜40 um, the diameter of the cladding is 200˜400 um, and fiber core is located at the center of cladding.

[0051] The fiber core is yttrium aluminum silicate material. By scanning electron microscope to observe the fiber core, obviously observed crystal precipitation, he crystal size is 50˜80 nm, and the crystal distribution is relatively uniform.

[0052] The active microcrystalline fiber passes the laser performance test and produces laser output with conversion efficiency over 30%.

Example 4

[0053] A method for processing active microcrystalline fiber by magnetic field induction and laserit, the specific steps are: Yb:YAG crystals with a doping concentration of 10 at % were processed into micron rods, their surfaces were polished, and the rods were inserted into the cleaned and dried quartz sleeve to make prefabricated rods. The prefabricated rod is fixed on the laser drawing furnace by aluminum fixture for wire drawing, in wire drawing; the doped fiber drawn is made to pass through an alternating magnetic field in an uncoated state. The two magnetic poles of the alternating magnetic field are vertically placed on both sides of the fiber, and the fiber coincide with the central axis of the two magnetic poles. The magnetic field intensity is 3T, and the carbon dioxide laser is turned on at the same time, laser processing power is 4W. The laser beam is focused and shaped into ring spots acting around the fiber, so that the fiber is heated evenly, and the diameter of the spot is 600 um. The core diameter of active microcrystalline optical fiber is 20˜40 um, the diameter of the cladding is 200˜400 um, and fiber core is located at the center of cladding.

[0054] The fiber core is yttrium aluminum silicate material. By scanning electron microscope to observe the fiber core, obviously observed crystal precipitation, he crystal size is 50˜80 nm, and the crystal distribution is relatively uniform.

[0055] The active microcrystalline fiber passes the laser performance test and produces laser output with conversion efficiency over 30%.

Example 5

[0056] A method for processing active microcrystalline fiber by magnetic field induction and laserit, the specific steps are: Yb:YAG crystals with a doping concentration of 10 at % were processed into micron rods, their surfaces were polished, and the rods were inserted into the cleaned and dried quartz sleeve to make prefabricated rods. The prefabricated rod is fixed on the laser drawing furnace by aluminum fixture for wire drawing, in wire drawing; the doped fiber drawn is made to pass through an alternating magnetic field in an uncoated state. The two magnetic poles of the alternating magnetic field are vertically placed on both sides of the fiber, and the fiber coincide with the central axis of the two magnetic poles. The magnetic field intensity is 0.1T, and the carbon dioxide laser is turned on at the same time, laser processing power is 0.3W. The laser beam is focused and shaped into ring spots acting around the fiber, so that the fiber is heated evenly, and the diameter of the spot is 150 um.

[0057] The core diameter of active microcrystalline optical fiber is 6˜12 um, the diameter of the cladding is 120˜150 um, and fiber core is located at the center of cladding.

[0058] The fiber core is yttrium aluminum silicate material. By scanning electron microscope to observe the fiber core, obviously observed crystal precipitation, he crystal size is 40˜60 nm, and the crystal distribution is relatively uniform.

[0059] The active microcrystalline fiber passes the laser performance test and produces laser output with conversion efficiency over 30%.

[0060] the grain size is smaller.