WO2020196626A1

WO2020196626A1 - Optical component and semiconductor laser module

Info

Publication number: WO2020196626A1
Application number: PCT/JP2020/013353
Authority: WO
Inventors: 橋本　博; 悠太石毛; 早水　尚樹; 那須　秀行
Original assignee: 古河電気工業株式会社
Priority date: 2019-03-28
Filing date: 2020-03-25
Publication date: 2020-10-01
Also published as: JPWO2020196626A1

Abstract

An optical component 10A is provided with: an optical fiber 112 having a core part 112a and a clad part 112b formed on the outer circumference of the core part; a glass capillary 116 disposed on the outer circumference of the clad part 112b; and a light absorber 117 disposed on the outer circumference of the glass capillary 116. An integrated part 122 in which the clad part 112b and the glass capillary 116 are integrated with each other in least the respective partial sections, is provided. A light reflection film 123 is provided to an input end surface 116a of the glass capillary 116. The integrated part 122 and the input end surface 116a to which the light reflection film 123 is provided are spaced apart from each other. The input end surface 116a has a tapered shape in which the diameter thereof becomes larger along a light traveling direction A. An end cap 124 is provided to an incident end part of the optical fiber 112. The integrated part 122 is provided to an anterior-half section with the light traveling direction A as a reference.

Description

Optical components and semiconductor laser modules

The present invention relates to optical components and semiconductor laser modules.

Semiconductor laser modules are also used in industrial fields such as processing and welding. In the semiconductor laser module, a glass capillary for fixing the optical fiber is provided on the outer periphery of the optical fiber as a configuration of a part for coupling the laser light output from the semiconductor laser element to the optical fiber, and the glass capillary is fixed on the outer periphery of the glass capillary. A configuration for providing a light absorber is disclosed. The optical fiber and the glass capillary are fixed with a first fixing agent such as resin. The glass capillary and the light absorber are fixed with a second fixing agent such as resin (Patent Document 1). In this configuration, a part of the laser beam input to the optical fiber propagates in the clad mode without being coupled to the core portion. Such laser light gradually leaks from the clad portion during propagation, passes through the two fixing agents and the glass capillary, reaches the light absorber, and is absorbed by the light absorber. According to the configuration of Patent Document 1, it is possible to suppress damage to the coating.

International Publication No. 2015/037725

In the industrial field, higher power of the laser beam of the light source is required. In the configuration of Patent Document 1, as the power of the laser beam increases, the power of the laser beam propagating in the clad mode among the laser beams increases. As a result, the laser beam propagating in the clad mode and leaking from the clad portion may damage the first or second adhesive. In particular, since the first fixing agent is adjacent to the outer periphery of the clad portion, the power density of the leaked laser beam is high, and the first fixing agent is more easily damaged than the second fixing agent.

The present invention has been made in view of the above, and an object of the present invention is to provide an optical component and a semiconductor laser module in which the occurrence of damage is suppressed.

In order to solve the above-mentioned problems and achieve the object, the optical component according to one aspect of the present invention includes an optical fiber having a core portion and a clad portion formed on the outer periphery of the core portion, and an outer periphery of the clad portion. A glass capillary arranged in a glass capillary and a light absorber arranged on the outer periphery of the glass capillary, and the clad portion and the glass capillary have an integrated portion integrated in at least a part of the section. It is a feature.

The optical component according to one aspect of the present invention is characterized in that a light reflecting film is provided on the input end surface of the glass capillary.

The optical component according to one aspect of the present invention is characterized in that the integrated portion and the input end surface provided with the light reflecting film are separated from each other.

The optical component according to one aspect of the present invention is characterized in that the end portion of the glass capillary has a tapered shape that gradually increases in diameter along the traveling direction of light.

The optical component according to one aspect of the present invention is characterized in that the integrated portion is provided in the first half portion with reference to the traveling direction of light.

The optical component according to one aspect of the present invention is characterized in that the integrated portion is integrated by welding.

The optical component according to one aspect of the present invention is characterized in that light is coupled to the input end face of the optical fiber via an end cap that reduces power density.

In the optical component according to one aspect of the present invention, the glass capillary includes a large diameter portion on the incident side and a small diameter portion on the light emitting side with respect to the large diameter portion, and the light absorber is the large diameter portion. It is provided with a first cylinder portion having an inner diameter corresponding to the diameter of the large diameter portion and a second cylinder portion having an inner diameter arranged on the outer circumference of the small diameter portion and having an inner diameter corresponding to the diameter of the small diameter portion. It is characterized by.

A semiconductor laser module according to one aspect of the present invention is characterized by including a semiconductor laser element and an optical system that guides a laser beam output from the semiconductor laser element to an input end face of the optical component.

According to the present invention, there is an effect that the occurrence of damage to the optical component and the semiconductor laser module is suppressed.

FIG. 1 is a schematic plan view of the semiconductor laser module according to the embodiment. FIG. 2 is a schematic cross-sectional view of the optical component and the optical fiber according to the first embodiment. FIG. 3 is a partially enlarged cross-sectional view of the optical component according to the first embodiment. FIG. 4 is an enlarged cross-sectional view of the integrated portion and its periphery. FIG. 5 is a schematic cross-sectional view of the optical component and the optical fiber according to the second embodiment. FIG. 6 is a schematic cross-sectional view of the optical component and the optical fiber according to the third embodiment. FIG. 7 is a schematic cross-sectional view of the optical component and the optical fiber according to the fourth embodiment. FIG. 8 is a schematic cross-sectional view of the optical component and the optical fiber according to the fifth embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments described below. Further, in the description of the drawings, the same or corresponding elements are appropriately designated by the same reference numerals, and duplicate description will be omitted as appropriate. In addition, it should be noted that the drawings are schematic, and the relationship between the dimensions of each element, the ratio of each element, etc. may differ from the reality.

(Semiconductor laser module)
FIG. 1 is a schematic plan view of the semiconductor laser module 100 according to the embodiment. The semiconductor laser module 100 includes the optical component 10 according to the embodiment. The semiconductor laser module 100 includes a package 101 which is a housing, an LD height adjusting plate 102 which is sequentially loaded inside the package 101, submounts 103-1 to 103-6, and six semiconductor laser elements 104-1. It is provided with ~ 104-6. Package 101 includes a lid, but is not shown in FIG. 1 for the sake of explanation. The semiconductor laser module 100 includes a lead pin 105 that injects a current into the semiconductor laser elements 104-1 to 104-6. The semiconductor laser module 100 is an optical element (optical system) sequentially arranged on the optical path of the laser light output by the semiconductor laser elements 104-1 to 104-6, that is, the first lenses 106-1 to 106-6. The second lens 107-1 to 107-6, the mirrors 108-1 to 108-6, the third lens 109, the optical filter 110, and the fourth lens 111 are provided. The first lens 106-1 to 106-6, the second lens 107-1 to 107-6, the mirror 108-1 to 108-6, the third lens 109, the optical filter 110, and the fourth lens 111 are each in the package 101. It is fixed inside. Further, the semiconductor laser module 100 includes an optical component 10 arranged so as to face the fourth lens 111, and an optical fiber 112 partially inserted into the optical component 10. One end of the optical fiber 112 on the side opposite to the side inserted into the optical component 10 extends to the outside of the package 101.

The semiconductor laser elements 104-1 to 104-6 are arranged at different heights from the bottom surface of the package 101 by the LD height adjusting plate 102. Further, the first lenses 106-1 to 106-6, the second lenses 107-1 to 107-6, and the mirrors 108-1 to 108-6 are arranged at the same height as one corresponding semiconductor laser element, respectively. There is. A loose tube 114 is provided at the insertion portion of the optical fiber 112 into the package 101, and the boot 113 is externally fitted to a part of the package 101 so as to cover a part of the loose tube 114.

Each semiconductor laser element 104-1 to 104-6 is supplied with electric power from the lead pin 105 to output laser light. Each of the output laser beams is regarded as substantially parallel light by the first lenses 106-1 to 106-6 and the second lenses 107-1 to 107-6, respectively. Next, each laser beam is reflected in the direction of the optical fiber 112 by one mirror 108-1 to 108-6 arranged at the corresponding height. Then, each laser beam is focused by the third lens 109 and the fourth lens 111.

The optical component 10 couples each laser beam focused by the fourth lens 111 to the optical fiber 112. The optical fiber 112 outputs each coupled laser beam to the outside of the semiconductor laser module 100.

Next, each component of the semiconductor laser module 100 will be described in more detail. The package 101, which is a housing, is preferably made of a material having good thermal conductivity in order to suppress an internal temperature rise, and may be a metal member made of various metals.

As described above, the LD height adjusting plate 102 is fixed in the package 101, adjusts the height of the semiconductor laser elements 104-1 to 104-6, and the semiconductor laser elements 104-1 to 104-6 The optical paths of the output laser beams do not interfere with each other. The LD height adjusting plate 102 may be integrally configured with the package 101.

The submounts 103-1 to 103-6 are fixed on the LD height adjusting plate 102, and assist the heat dissipation of the mounted semiconductor laser elements 104-1 to 104-6. Therefore, the submounts 103-1 to 103-6 are preferably made of a material having good thermal conductivity, and may be a metal member made of various metals.

The semiconductor laser elements 104-1 to 104-6 are high-output semiconductor laser elements having an output laser light intensity of 1 W or more and further 10 W or more. In the present embodiment, the light intensity of the laser light output by the semiconductor laser devices 104-1 to 104-6 is, for example, 11 W. Further, the semiconductor laser elements 104-1 to 104-6 output laser light having a wavelength of, for example, 900 nm to 1000 nm. Although the semiconductor laser module 100 includes six semiconductor laser elements 104-1 to 104-6, a plurality of semiconductor laser elements other than the six or one may be used.

The lead pin 105 supplies electric power to the semiconductor laser elements 104-1 to 104-6 via a bonding wire (not shown). The power to be supplied may be a constant voltage, but may be a modulated voltage.

The first lenses 106-1 to 106-6 are, for example, cylindrical lenses having a focal length of 0.3 mm. The first lenses 106-1 to 106-6 are arranged at positions where the output light of one corresponding semiconductor laser element is substantially parallel light in the vertical direction.

The second lenses 107-1 to 107-6 are, for example, cylindrical lenses having a focal length of 5 mm. The second lenses 107-1 to 107-6 are arranged at positions where the output light of the semiconductor laser element is substantially parallel light in the horizontal direction.

The mirrors 108-1 to 108-6 may be mirrors provided with various metal films or dielectric films, and have high reflectance at the wavelength of the laser beam output by the semiconductor laser elements 104-1 to 104-6. Is more preferable. Further, the mirrors 108-1 to 108-6 can finely adjust the reflection direction so that the laser beam of one corresponding semiconductor laser element is suitably coupled to the optical fiber 112.

The third lens 109 and the fourth lens 111 are, for example, cylindrical lenses having focal lengths of 12 mm and 5 mm and having orthogonal curvatures to each other, and condense the laser light output by the semiconductor laser elements 104-1 to 104-6. , Suitable for coupling to the optical fiber 112. The positions of the third lens 109 and the fourth lens 111 with respect to the optical fiber 112 are such that, for example, the coupling efficiency of the laser light output by the semiconductor laser elements 104-1 to 104-6 to the optical fiber 112 is 85% or more. Has been adjusted.

The optical filter 110 is, for example, a low-pass filter that reflects light having a wavelength of 1060 nm to 1080 nm and transmits light having a wavelength of 900 nm to 1000 nm. As a result, the optical filter 110 transmits the laser light output by the semiconductor laser elements 104-1 to 104-6, and the semiconductor laser elements 104-1 to 104-6 are irradiated with light having a wavelength of 1060 nm to 1080 nm from the outside. To prevent that. Further, the optical filter 110 is used to prevent the output laser light of the semiconductor laser elements 104-1 to 104-6 slightly reflected by the optical filter 110 from returning to the semiconductor laser elements 104-1 to 104-6. It is arranged at an angle to the optical axis. The passing wavelength of the optical filter 110 is set to 1060 nm to 1080 nm, but the wavelength is not limited to this wavelength. However, the optical filter 110 is not always necessary.

The boot 113 is inserted with the optical fiber 112 to prevent damage due to bending of the optical fiber 112. The boot 113 may be a metal boot, but the material is not particularly limited, and rubber, various resins, plastic, or the like may be used. However, boots 113 are not always necessary.

The loose tube 114 is inserted with an optical fiber 112 to prevent damage due to bending of the optical fiber 112. Further, the loose tube 114 is fixed to the optical fiber 112, and as a result, the position of the optical fiber 112 is prevented from being displaced when a pulling force is applied to the optical fiber 112 in the longitudinal direction. May be good. However, the loose tube 114 is not always necessary.

The optical component 10 in the semiconductor laser module 100 removes or removes a part of the laser light input to the optical fiber 112 that propagates in the clad mode without being coupled to the core portion (hereinafter, referred to as clad mode light). It is a component to be reduced, and specifically, any one of the optical components 10A to 10E described below is preferably applied. The optical components 10A to 10E may be applied by combining the respective components with each other. The optical components 10A to 10E will be described in order.

(Optical components according to the first embodiment)
First, the configuration of the optical component 10A according to the first embodiment will be specifically described. FIG. 2 is a schematic cross-sectional view of the optical component 10A and the optical fiber 112.

As shown in FIG. 2, the optical component 10A includes a part of the above optical fiber 112. The optical fiber 112 is an optical fiber made of a quartz glass-based material, and has a core portion 112a and a clad portion 112b formed on the outer periphery of the core portion 112a. The outer periphery of the clad portion 112b of the optical fiber 112 is further covered with a covering material 112c. The refractive index of the clad portion 112b is lower than that of the core portion 112a.

The optical fiber 112 may be, for example, a multimode optical fiber having a core diameter of 105 μm in the core portion 112a and a clad diameter of 125 μm in the clad portion 112b, but may be a single mode optical fiber. The NA of the optical fiber 112 is, for example, 0.15 to 0.22.

The optical component 10A further includes a glass capillary 116 arranged on the outer periphery of the clad portion 112b and a light absorber 117 arranged on the outer periphery of the glass capillary 116. One end of the optical fiber 112 is inserted through the glass capillary 116. The optical fiber 112 includes a covering material 112c, but the covering material 112c is removed from the portion of the optical fiber 112 to be inserted into the glass capillary 116 except for the insertion side end portion, and the core portion 112a and the clad portion 112b are formed. It is inserted through the glass capillary 116. In the present application, the portion of the core portion 112a and the clad portion 112b excluding the covering material 112c may be referred to as an optical fiber 112. The covering material 112c is fixed to the end face of the glass capillary 116 by the fixing material 121. As the fixing material 121, for example, the same one as the first fixing agent 119 can be used, or an appropriate fixing tool can be used.

The glass capillary 116 is a circular tubular glass capillary having a through hole. An optical fiber 112 is inserted through the through hole of the glass capillary 116, and the inner wall of the through hole of the glass capillary 116 and a part of the clad portion 112b are fixed with the first fixing agent 119. The glass capillary 116 has light transmittance at the wavelength of the laser beam L (see FIG. 2) output by the semiconductor laser elements 104-1 to 104-6, and is, for example, a material having a transmittance of 90% or more at this wavelength. It is preferably composed of. The refractive index of the glass capillary 116 is preferably equal to or higher than the refractive index of the clad portion 112b of the optical fiber 112. For example, the refractive index of the glass capillary 116 is the specific refractive index of the optical fiber 112 with respect to the clad portion 112b. The difference is 0.1% or more and 10% or less. The glass capillary 116 may be provided with a tapered portion provided on the light emitting side so that the optical fiber 112 can be easily inserted.

The first fixing agent 119 is provided in the latter half of the optical component 10A with reference to the traveling direction A of light, and more preferably is provided in a part near the output end. The first fixing agent 119 is made of a UV curable resin such as an epoxy resin or a urethane-based resin. The refractive index of the first fixing agent 119 is preferably equal to or higher than the refractive index of the clad portion 112b of the optical fiber 112 at 25 ° C., and is in the operating temperature range of the semiconductor laser module 100 (for example, 15 ° C. to 100). In ° C.), it is more preferable that the refractive index is equal to or higher than the refractive index of the clad portion 112b of the optical fiber 112. As for the refractive index of the first fixing agent 119, for example, the difference in the specific refractive index with respect to the clad portion 112b is 0% or more and 10% or less. Further, it is preferable that the thickness of the first fixing agent 119 in the direction orthogonal to the longitudinal direction of the optical fiber 112 is 1 μm or more and 800 μm or less. It is known that the UV curable resin can have a low refractive index by containing fluorine and a high refractive index by containing sulfur, and it is known that a material having a high refractive index or a material having a low refractive index can be used. The refractive index can be adjusted by adjusting the content.

The light absorber 117 is a tubular member, is arranged on the outer periphery of the glass capillary 116, and is fixed to the glass capillary 116 with a second fixing agent 120. The light absorber 117 has a light absorption property at the wavelength of the laser beam L (see FIG. 2), and the absorption rate is, for example, 30% or more, preferably 70% or more at this wavelength. As a result, the light absorber 117 absorbs the clad mode light leaked from the clad portion 112b via the glass capillary 116. The light absorber also absorbs laser light (hereinafter referred to as capillary mode light) that is coupled to the glass capillary 116 and propagates in the capillary mode.

Further, since the light absorber 117 dissipates heat generated by light absorption, it is preferably made of a material having good thermal conductivity, for example, a metal member containing Cu, Ni, stainless steel, or Fe, Ni, Cr, etc. metal containing Ti or member comprising a surface plating layer containing C,, AlN, or ceramic member including an _Al 2 _{O 3} or AlN, or be made of a member having a ceramic layer covering the surface including the _Al 2 _{O 3,} preferable. Further, in order to dissipate heat generated by light absorption, the light absorber 117 is preferably connected to the package 101 via a good heat conductor (not shown). The thermally good conductor is preferably made of a material having a thermal conductivity of 0.5 W / mK or more, and is made of, for example, solder or a thermally conductive adhesive.

The glass capillary 116 and the light absorber 117 are fixed with the second fixing agent 120 as described above. The second fixing agent 120 fixes the glass capillary 116 and the light absorber 117 over the entire length. The second fixing agent 120 may be made of the same material as the first fixing agent 119, but may be made of a different material, and is made of a UV curable resin such as an epoxy resin or a urethane-based resin. The refractive index of the second adhesive 120 is preferably equal to or higher than the refractive index of the glass capillary 116 at 25 ° C., and in the operating temperature range of the semiconductor laser module 100 (for example, 15 ° C. to 100 ° C.). More preferably, it is equal to or higher than the refractive index of the glass capillary 116.

The clad portion 112b and the glass capillary 116 are provided with an integrated portion 122 integrated in a part of the section. The integrated portion 122 is a portion in which the clad portion 112b and the glass capillary 116 are continuously integrated without interposing other members, and is, for example, welded as will be described later. The integrated portion 122 is a portion for deriving the clad mode light from the clad portion 112b to the glass capillary 116 as described later.

The input end surface 116a of the glass capillary 116 has a tapered shape that gradually increases in diameter along the traveling direction A of light, and the input end surface 116a is provided with a light reflecting film 123. The integrated portion 122 is provided in the first half of the optical component 10A with the light traveling direction A as a reference, and is appropriately separated from the input end surface 116a provided with the light reflecting film 123.

The optical component 10A further includes an end cap 124 that reduces the power density of the combined laser beam L, and light is coupled to the input end face of the optical fiber 112 via the end cap 124. The end cap 124 includes a truncated cone-shaped output unit 124a and a cylindrical input unit 124b. The material of the end cap 124 is preferably a material having a refractive index similar to that of the core portion 112a of the optical fiber 112, and is preferably a quartz glass material having the same refractive index as that of the core portion 112a of the optical fiber 112, for example. The laser beam L focused by the fourth lens 111 is input to the end cap 124 from the bottom surface of the input unit 124b. The shape of the end cap 124 is not limited to the one shown in the figure, and may be any shape that can reduce the power density. The end cap 124 is welded to, for example, the input end of the optical fiber 112.

FIG. 3 is a partially enlarged cross-sectional view of the optical component 10A. As shown in FIG. 3, the inner surface 117a of the light absorber 117 is provided with irregularities on the entire surface thereof. The unevenness of the inner surface 117a has, for example, a height of about 10 μm. The second fixing agent 120 is interposed between the outer surface of the glass capillary 116 and the inner surface 117a of the light absorber 117.

A clearance 126 is formed between the clad portion 112b and the glass capillary 116. The clearance 126 is formed in a section other than the fixing portion and the integral portion 122 of the first fixing agent 119. The width of the clearance 126 is set to, for example, 5 μm or less (2.5 μm or less on one side) on a diameter basis based on some requirements. One of the requirements for defining the width of the clearance 126 is that the optical fiber 112 can be easily inserted into the penetration portion of the glass capillary 116. Another requirement is that the clearance 126 is sufficiently narrow to allow the clad mode light to be easily derived. Yet another requirement is that the clearance 126 is narrow enough to allow the integral portion 122 to be machined. Yet another requirement is that the machining accuracy requirements are met.

Here, the manufacturing method of the optical component 10A will be described with reference to FIG. First, the light reflecting film 123 is deposited on the input end surface 116a of the glass capillary 116. At this point, since the optical fiber 112 is not inserted through the glass capillary 116, the material of the light reflecting film 123 does not adhere to the optical fiber 112.

Next, the optical fiber 112 from which the covering material 112c at one end has been stripped is inserted into the glass capillary 116. Then, the first fixing agent 119 is permeated through the gap between the glass capillary 116 and the optical fiber 112 while being held at a predetermined position, and cured (for example, UV curing). As a result, the first fixing agent 119 is provided near the light emitting end of the optical component 10A. The inserted optical fiber 112 is fixed by the first fixing agent 119. The optical fiber 112 is further fixed by the fixing material 121.

Then, the outer surface of the clad portion 112b and the inner surface of the glass capillary 116 are integrated by welding over a predetermined length X to form an integrated portion 122. This welding process is performed by heating the target portion with, for example, a burner or an electric discharge, and is processed over the entire circumference. In addition to heat welding, the integrated portion 122 may be, for example, ultrasonic welding or crimping. Since the integrated portion 122 and the input end surface 116a provided with the light reflecting film 123 are appropriately separated from each other, the thermal effect on the light reflecting film 123 is sufficiently small. The integrated portion 122 also has an action of fixing the clad portion 112b and the glass capillary 116.

The length X of the integral portion 122 is preferably sufficiently long in order to derive the clad mode light, but on the other hand, the length X is appropriately short in order to suppress the influence of heat due to welding on the optical fiber 112. Is desirable. After all, the length X needs to be long enough to derive the clad mode light, and further, the power density can be sufficiently lowered even if some clad mode light remains. I just need it.

After that, the glass capillary 116 is inserted through the light absorber 117, and both are fixed with the second fixing agent 120. Further, the end cap 124 is attached.

Next, the operation of the optical component 10A configured in this way will be described.

As shown in FIG. 2, the laser beam L coupled to the optical component 10A is coupled to the incident end of the optical fiber 112 after passing through the end cap 124. By passing the laser beam L through the end cap 124, the power density is appropriately reduced, and damage to the input end of the optical fiber 112 is prevented.

As described above, the laser beam L is focused by the fourth lens 111 (see FIG. 1), most of which is coupled to the core portion 112a and transmitted by the optical fiber 112. On the other hand, the laser beam L1 which is a part of the laser beam L that is not coupled to the core portion 112a is coupled to the clad portion 112b, and the laser beam L2 of a part of the non-coupling light is a glass capillary. The input end face 116a of 116 is irradiated.

Since the light reflecting film 123 is provided on the input end surface 116a, the laser light L2 is prevented from being reflected by the light reflecting film 123 and being bonded to the glass capillary 116. Further, since the input end surface 116a has a tapered shape in which the diameter gradually increases along the traveling direction A of the light, the reflected laser beam L2 goes in a direction away from the central axis and does not return to the light source direction. As described above, the tapered input end surface 116a and the light reflecting film 123 have a synergistic action for dispersing the laser beam L2 without being coupled to the glass capillary 116. The input end surface 116a has a tapered shape, the central angle of the conical surface is, for example, about 150 °, and the reflected light of the laser beam L2 spreads in the direction opposite to the arrow A. Further, the center angle of the conical surface of the input end surface 116a may be set to 90 ° or less so that the reflected light of the laser light L2 spreads in the direction of the arrow A.

FIG. 4 is an enlarged cross-sectional view of the integrated portion 122 and its surroundings. As shown in FIG. 4, the laser beam L1 coupled to the clad portion 112b becomes clad mode light, but eventually reaches the integrated portion 122. Since the clad portion 112b and the glass capillary 116 are integrated in the integrated portion 122, the clad mode light is led out from the clad portion 112b to the glass capillary 116 without being reflected.

Since the integral portion 122 is set to an appropriate length X, most of the clad mode light escapes from the clad portion 112b to the glass capillary 116, or the power density is sufficiently reduced, and the first fixing agent is used. Local heating does not damage 119 and the like. In particular, the first fixing agent 119 is adjacent to the outer periphery of the clad portion 112b, but is provided sufficiently separated from the input end surface 116a and the integrated portion 122 to prevent damage. It should be noted that the integrated portion 122 has a corresponding effect as long as it is provided in at least a part of the total length of the insertion portion of the clad portion 112b with respect to the glass capillary 116 in the optical component 10A.

Further, the integrated portion 122 is provided in the first half portion of the optical component 10A with reference to the traveling direction A of light. Therefore, the laser beam L1 that has passed through the integrated portion 122 and is coupled to the glass capillary 116 passes through the glass capillary 116 and reaches the light absorber 117 before reaching the exit side end portion, and is reached by the light absorber 117. Be absorbed. Further, since the inner surface 117a (see FIG. 3) of the light absorber 117 is formed with irregularities, the laser beam L1 not absorbed by the light absorber 117 is diffusely reflected at this boundary surface and the energy is dispersed. ..

(Optical components according to the second embodiment)
FIG. 5 is a schematic cross-sectional view of the optical component 10B and the optical fiber 112 according to the second embodiment. As shown in FIG. 5, in the optical component 10B, the input end surface 116a is flat and is flush with the optical fiber 112 and the light absorber 117, and the light reflecting film 123 (see FIG. 2) is not provided. .. That is, when the focusing accuracy of the laser beam L is high and there is almost no laser beam L2 (see FIG. 2) coupled to the input end face 116a, the capillary mode light is not generated, so that the input end face 116a does not need to be tapered. Also, it is not necessary to provide the light reflecting film 123. In this case, the glass capillary 116 does not need to be tapered for the input end face 116a and is easy to manufacture.

In the optical component 10B, the integrated portion 122 is formed over the entire section of the boundary surface between the clad portion 112b and the glass capillary 116. That is, when it is possible to heat accurately by the welding process when forming the integrated portion 122, the influence of thermal strain on the optical fiber 112 is reduced, so that the integrated portion 122 is formed sufficiently long. May be good. Since the optical component 10B is not provided with the light reflecting film 123, the integrated portion 122 can be formed up to a position in contact with the input end surface 116a. When the integral portion 122 is formed to a position in contact with the input end surface 116a, the clad mode light can be led out to the glass capillary 116 at a further initial stage. Further, when the integrated portion 122 is formed sufficiently long, it becomes easy to lead the clad mode light to the glass capillary 116.

(Optical components according to the third embodiment)
FIG. 6 is a schematic cross-sectional view of the optical component 10C and the optical fiber 112 according to the third embodiment. As shown in FIG. 6, in the optical component 10C, the input end surface 116a is flat and has the same surface shape as the optical fiber 112 and the light absorber 117, and the input end surface 116a is provided with the light reflecting film 123. There is. That is, if the light reflecting film 123 is provided, the laser beam L2 does not bind to the glass capillary 116, so that the capillary mode light is not generated. Further, when the focusing accuracy of the laser beam L is high and the laser beam L2 coupled to the input end face 116a is weak, no special measure is required for the reflection direction of the laser beam L2 and the input end face 116a does not have to be tapered. May be good.

In the optical component 10C, the integrated portion 122 is formed over almost the entire section of the boundary surface between the clad portion 112b and the glass capillary 116, but is appropriately separated from the input end surface 116a and the integrated portion 122 is welded. Sometimes there is no thermal effect on the light reflecting film 123.

(Optical components according to the fourth embodiment)
FIG. 7 is a schematic cross-sectional view of the optical component 10D and the optical fiber 112 according to the fourth embodiment. As shown in FIG. 7, in the optical component 10D, the input end surface 116a is flat and is flush with the optical fiber 112 and the light absorber 117, and the light reflecting film 123 (see FIG. 2) is not provided. .. This is the same as the optical component 10B (see FIG. 5).

In the optical component 10D, the integrated portion 122 is formed over a length X1 with reference to the input end face 116a. The integrated portion 122 is provided in the first half portion with reference to the traveling direction A of light, and is equal to or somewhat longer than the length X (see FIG. 2) of the optical component 10A. Since the light reflecting film 123 (see FIG. 2) is not provided, the integrated portion 122 can be formed up to a position in contact with the input end surface 116a, and the clad mode light can be led out to the glass capillary 116 at a further initial stage.

At the boundary surface between the clad portion 112b and the glass capillary 116, the first fixing agent 119 is provided in the section on the light emitting side of the integrated portion 122, and the clad portion 112b and the glass capillary 116 are fixed. If the clad mode light can be sufficiently derived to the glass capillary 116 in the integrated portion 122, the first fixing agent 119 in the remaining section is not damaged, and the clad portion 112b and the glass capillary 116 are more reliably fixed. can do.

(Optical components according to the fifth embodiment)
FIG. 8 is a schematic cross-sectional view of the optical component 10E and the optical fiber 112 according to the fifth embodiment. As shown in FIG. 8, in the optical component 10E, the glass capillary 116 includes a large diameter portion 116b on the incident side and a small diameter portion 116c on the output side of the large diameter portion 116b.

The large diameter portion 116b includes an extension portion 127a in which the small diameter portion 116c is extended to the incident side with a constant diameter, and a tubular portion 127b provided on the outer periphery of the extension portion 127a. For the large diameter portion 116b, the tubular portion 127b may be provided after the integral portion 122 is welded and formed on the boundary surface between the extension portion 127a and the clad portion 112b. The extension portion 127a and the tubular portion 127b may be fixed, welded, or preliminarily integrated with, for example, the first fixing agent 119 with a homogeneous agent. The extension portion 127a and the cylinder portion 127b may be made of the same material, for example.

Further, the light absorber 117 in the optical component 10E is arranged on the outer periphery of the large diameter portion 116b and has an inner diameter corresponding to the diameter of the large diameter portion 116b, and is arranged on the outer periphery of the small diameter portion 116c. It is provided with a second tubular portion 117c having an inner diameter corresponding to the diameter of the small diameter portion 116c. Concavities and convexities (see FIG. 3) are formed on the inner surfaces 117a of the first tubular portion 117b and the second tubular portion 117c. The tubular portion 127b of the glass capillary 116 and the second tubular portion 117c of the light absorber 117 are in contact with each other on a stepped surface 128. The step surface 128 is a surface orthogonal to the traveling direction A of light.

According to the optical component 10E, the laser beam L1 bonded to the cladding portion 112b becomes a cladding mode light, then when it is derived from the integral portion 122 to the glass capillary 116, proceeds as leakage light L1 ₀ indicated by the arrow .. Then, the leakage light L1 ₀ is before reaching the inner surface 117a of the light absorber 117, consisting mostly is absorbed by the light absorber 117 reaches the stepped surface 128 easily. Since the leakage light L1 ₀ is larger incident angle with respect to the stepped surface 128, it tends to be absorbed by the light absorber 117 than when incident on the inner surface 117a.

Further, in the above embodiment, the end structure is used for coupling a laser beam output from a light source such as a semiconductor laser element to an optical fiber. However, the use of the end structure is not limited to this. For example, the end structure may be provided on the output side of a processing laser device using a fiber laser or the like, for example, on the output side of a delivery optical fiber such as a head portion. In the processing laser device, the laser beam irradiated to the processing target may be reflected and returned. When such return light propagates in the optical fiber constituting the processing laser device in the clad mode, a part of the return light may leak from the clad portion and damage the device. Therefore, by providing the end structure on the output side of the processing laser apparatus, it is possible to suppress or prevent the propagation of the return light in the clad mode.

In the above embodiment, the laser beam having a wavelength in the infrared region is taken as an example, but the wavelength is not limited to this. For example, in the case of a short wavelength laser beam such as green or blue, the amount of energy absorbed by the fixing material is larger than that of the laser beam having a wavelength in the infrared region, and the effect of the present invention may become more remarkable. ..

Further, the present invention is not limited to the above-described embodiment, and it goes without saying that the present invention can be freely changed without departing from the gist of the present invention.

The present invention can be used for optical components and semiconductor laser modules.

10, 10A, 10B, 10C, 10D, 10E Optical component 100 Semiconductor laser module 101 Package 102 LD Height adjustment plate 103-1 to 103-6 Submount 104-1 to 104-6 Semiconductor laser element 105 Lead pin 106-1 to 106-6 1st lens 107-1 to 107-6 2nd lens 108-1 to 108-6 Mirror 109 3rd lens 110 Optical filter 111 4th lens 112 Optical fiber 112a Core part 112b Clad part 112c Coating material 113 Boots 114 Loose tube 116 Glass capillary 116a Input end surface 116b Large diameter part 116c Small diameter part 117 Light absorber 117a Inner surface 117b First cylinder part 117c Second cylinder part 119 First fixing agent 120 Second fixing agent 121 Fixing material 122 Integrated part 123 Light reflection Film 124 End cap 124a Output part 124b Input part 126 Clearance 127a Extension part 127b Cylinder part 128 Step surface L, L1, L2 Laser light L10 Leakage light

Claims

An optical fiber having a core portion and a clad portion formed on the outer periphery of the core portion,
The glass capillaries arranged on the outer periphery of the clad portion and
A light absorber arranged on the outer periphery of the glass capillary and
With
An optical component characterized in that the clad portion and the glass capillary have an integrated portion integrated in at least a part of the section.
The optical component according to claim 1, wherein a light reflecting film is provided on the input end surface of the glass capillary.
The optical component according to claim 2, wherein the integrated portion and the input end surface provided with the light reflecting film are separated from each other.
The optical component according to claim 1 or 2, wherein the end portion of the glass capillary has a tapered shape that gradually increases in diameter along the traveling direction of light.
The optical component according to any one of claims 1 to 4, wherein the integrated portion is provided in the first half portion with reference to the traveling direction of light.
The optical component according to any one of claims 1 to 5, wherein irregularities are formed on the inner surface of the light absorber.
The optical component according to any one of claims 1 to 6, wherein the integrated portion is integrated by welding.
The optical component according to any one of claims 1 to 7, wherein light is coupled to the input end face of the optical fiber via an end cap that reduces power density.
The glass capillary includes a large-diameter portion on the incident side and a small-diameter portion on the light emitting side of the large-diameter portion.
The light absorber is arranged on the outer periphery of the large diameter portion and has an inner diameter of a first cylinder portion corresponding to the diameter of the large diameter portion and an inner diameter corresponding to the diameter of the small diameter portion arranged on the outer circumference of the small diameter portion. The optical component according to any one of claims 1 to 8, further comprising a second tubular portion.
The optical component according to any one of claims 1 to 9,
Semiconductor laser element and
An optical system that guides the laser beam output from the semiconductor laser element to the input end face of the optical component, and
A semiconductor laser module characterized by being equipped with.