JP2003131079A - Optical connector for laser and laser guide - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely prevent a part around fiber inserting hole 10 from being damaged by irradiation of the part around the fiber inserting hole 10 of a sleeve 7 in connecters C1 and C2 with incident laser beam due to a misalignment of reflective laser beam from a processed product, optical connectors C1 and C2 and a laser oscillating device, when a laser guide G that installs the optical connectors C1 and C2 for laser wherein the fiber inserting hole 10 has an open sleeve 7 in each edge of the outgoing side and incoming side of a fiber F for sending the laser beam is connected with the laser oscillating device, a high- power laser beam from the laser oscillating device is outputted in the processed product through the laser guide G, and the processed part is welded and processed or cut or processed. SOLUTION: A chip part 9 wherein the fiber inserting hole 10 is open is installed in the edge wall part 7a of the sleeve 7, a reflective surface 16 of the laser beam is formed by coating processing on a surface of the chip part 9 with an evaporation coat, and the reflective laser beam or the incidence laser beam irradiated on the surface of the chip part 9 is reflected and enlarged on the reflective surface 16.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technical field relating to a laser optical connector mounted on an incident end and an emitting end of an optical fiber for transmitting laser light, and a laser guide including a combination thereof.

[0002]

2. Description of the Related Art Conventionally, a laser processing apparatus for performing various kinds of processing on a workpiece, such as welding or cutting metal by using high-power laser light from a YAG laser or the like, is generally well known. There is. In such a laser processing device, a laser guide is connected to an output part of a laser oscillation device that oscillates and amplifies laser light via an incident side lens part, and the laser beam output from the laser oscillation device is a condensing lens of the lens part. After the light is focused by the laser guide, it is made to enter the optical fiber of the laser guide from the entrance end to be transmitted through the core, emitted from the exit end of this optical fiber, and then collected by the condenser lens of the exit side lens part. By irradiating the workpiece, the portion to be processed is processed.

The laser guide is equipped with an optical connector for connecting to the lens portion at the entrance end and the exit end of the optical fiber. This laser optical connector is provided with, for example, a bottomed cylindrical metal sleeve having a fiber insertion hole formed in the tip wall portion (bottom wall portion), and the end portion of the optical fiber is fitted into the sleeve. At the end of the optical fiber, an exposed part is formed by removing the protective layer from the tip to expose the fiber core wire consisting of the core and the clad, and the exposed part of the fiber core wire and the subsequent protective layer are formed. The optical fiber end is fitted into the sleeve. Then, of the optical fiber inserted into this sleeve, the tip of the exposed portion of the fiber core wire is inserted into the fiber insertion hole of the sleeve, and the protective layer is fixed to the sleeve by a fixing portion such as a chuck mechanism provided in the sleeve. Is held.

Further, a through hole is formed in the distal end wall portion of the sleeve, and a chip portion which has a fiber insertion hole and is separate from the sleeve is fitted and fixed in the through hole, in other words, the fiber insertion hole. It is also practiced to configure the surroundings with a chip part.

[0005]

By the way, when a high-power laser beam is transmitted through an optical fiber to process a work piece, the work piece is easily reflected, for example, aluminum or zinc-plated material. When it is a metal or the like, a part of the laser light condensed by the condenser lens after being emitted from the optical fiber is reflected by the workpiece, and the reflected laser light returns to the connector side through the condenser lens, There is a problem that the reflected laser light damages the vicinity of the fiber insertion hole of the sleeve. Particularly, when the tip portion is provided on the tip wall portion of the sleeve as described above, the tip portion is damaged. The area around the condenser lens is covered with a shielding material, and the reflected laser light that does not enter the condenser lens is reflected by the shielding material, so only the reflected laser light incident on the condenser lens is collected. It is illuminated and returns to the vicinity of the fiber insertion hole of the sleeve.

Further, even at the incident end of the optical fiber, if there is misalignment (misalignment) of the optical axis between the condenser lens on the side of the laser oscillator and the optical connector, the incident laser light will be reflected by the sleeve. This will damage the vicinity of the fiber insertion hole and the tip portion.

Therefore, it is conceivable to use a material having high light resistance against laser light (for example, sapphire) as the chip portion having the fiber insertion hole.
This is not an essential solution, and when the laser oscillator output is higher and a higher-power laser beam is used, the area around the fiber insertion hole (tip portion) of the sleeve is still damaged. It is inevitable to do.

On the other hand, even when the reflected laser light or the incident laser light does not hit the vicinity of the fiber insertion hole of the sleeve, for example, the insertion occurs between the fiber insertion hole of the sleeve and the fiber core of the optical fiber. May penetrate into the sleeve through the gaps for clearance, the clad of the fiber core wire, the transparent tip, etc. (see FIG. 5). In that case, the laser light entering the sleeve causes the protective layer of the optical fiber to The problem of being damaged arises.

The present invention has been made in view of the above points, and an object thereof is to provide a laser light connector with reflected laser light from a workpiece or an incident laser light due to misalignment by making a certain improvement on the optical connector for laser. It is intended to surely prevent the damage of the peripheral portion of the fiber insertion hole of the sleeve and the optical fiber protective layer in the sleeve by the irradiation of.

[0010]

In order to achieve the above object, according to the present invention, a portion of a sleeve of an optical connector for a laser to which a reflected laser light from a workpiece or an incident laser light due to misalignment is irradiated is a laser. A light reflecting surface is provided or a shielding member is provided.

Specifically, according to the first aspect of the present invention, a laser light is formed by coating a fiber core wire consisting of a core and a clad with a protective layer, and is attached to an end portion of a laser optical fiber for transmitting laser light. As the connector, the end portion of the optical fiber in which the protective layer is removed from the tip and the exposed portion of the fiber core wire is formed is fitted over the exposed portion and the protective layer,
A sleeve provided with a fiber insertion hole through which a tip of the exposed portion of the fiber core is inserted in the tip wall portion; and a fixing portion for fixing and holding the end portion of the optical fiber with a protective layer in the sleeve. To do. Then, a reflecting surface for reflecting laser light is provided at least in the vicinity of the fiber insertion hole on the outer surface of the distal end wall portion of the sleeve.

According to the above construction, the end portion of the optical fiber having the exposed portion where the protective layer is removed from the tip and the fiber core wire is exposed in the sleeve of the optical connector for laser extends over the exposed portion and the protective layer. The end portion of the optical fiber is fixedly held by the fixing portion to the sleeve by the protective layer, and the tip of the exposed portion of the fiber core is inserted into the fiber insertion hole of the sleeve. An optical connector for laser is attached to the end of the fiber.

When processing a workpiece by transmitting laser light through the optical fiber, if the workpiece is of a type that is easily reflected, a part of the laser light emitted from the optical fiber will be covered. It is reflected by the work piece and returns to the connector side, and the reflected laser light hits the vicinity of the fiber insertion hole on the tip wall of the sleeve, but the laser light is reflected at least near the fiber insertion hole on the outer surface of the tip wall of the sleeve. Since the surface is provided, even if the reflected laser light strikes it, it is reflected by the reflecting surface and diffuses. As a result, it is possible to reliably prevent damage in the vicinity of the fiber insertion hole of the sleeve.

Further, even if the incident laser beam hits the vicinity of the fiber insertion hole of the sleeve due to misalignment of the optical axis between the optical connector at the incident side end of the optical fiber and the laser oscillator side, the incident laser beam is incident. The laser light is also reflected by the reflecting surface and diffused. Therefore, also in this case, damage in the vicinity of the fiber insertion hole of the sleeve can be reliably prevented.

According to a second aspect of the present invention, similarly to the first aspect of the present invention, a fiber core wire composed of a core and a clad is covered with a protective layer, and the end portion of an optical fiber for laser transmitting laser light is provided. As an optical connector for a laser to be attached, an end portion of an optical fiber in which a protective layer is removed from a tip and an exposed portion of a fiber core wire is formed is inserted into the exposed portion and the protective layer, and the end wall portion is provided with the above. It is assumed that a sleeve is provided with a fiber insertion hole for inserting the tip of the exposed portion of the fiber core wire, and a fixing portion for fixing and holding the end portion of the optical fiber with a protective layer in the sleeve. Then, at least one shielding member having a fiber insertion hole is provided in the sleeve in a state where the exposed portion of the fiber core wire is inserted into the fiber insertion hole.

As a result, the reflected laser light and the incident laser light pass through the gap between the fiber insertion hole of the sleeve and the fiber core wire of the optical fiber, the clad of the fiber core wire, the transparent chip portion, etc., inside the sleeve. Even if it penetrates into the optical fiber, the laser light that has entered will be shielded by the shielding member that is inserted through the exposed portion of the fiber core between the fiber insertion hole of the sleeve and the protective layer of the optical fiber, and the laser light will be protected. The protective layer of the optical fiber can be reliably prevented from being damaged because it does not hit the layer.

According to a third aspect of the present invention, in the laser optical connector according to the first aspect, at least one shielding member having a fiber insertion hole is inserted into the sleeve of the optical connector, and the exposed portion of the fiber core wire is inserted into the fiber insertion hole. It is provided in the condition that In this case, the respective operational effects of the inventions of claims 1 and 2 are synergistically obtained.

According to the fourth aspect of the present invention, the tip wall portion of the sleeve is provided with a tip portion having a fiber insertion hole, and a reflection surface is formed on the outer surface of the tip portion. As a result, the reflecting surface can be formed by the tip portion itself, which is separate from the sleeve, and the structure of the reflecting surface can be embodied.

According to the fifth aspect of the invention, the tip wall portion of the sleeve is provided with a tip portion having a fiber insertion hole, and a reflection surface is formed on the outer surface of the tip portion by coating. In this case, the outer surface of the tip portion, which is separate from the sleeve, can be coated to form a reflective surface, and the structure of the reflective surface can be embodied.

According to the sixth aspect of the present invention, the tip side surface of the shielding member is provided as a reflecting surface for reflecting the laser beam. By doing so, even if the laser light that has entered the sleeve through the fiber insertion hole or the transparent tip portion hits the shield member, it will be reflected and diffused by the reflective surface of the shield member, thus damaging the shield member itself. Therefore, damage to the protective layer of the optical fiber can be stably and reliably prevented.

In the invention of claim 7, the fiber insertion hole of the sleeve is a cylindrical hole having the same diameter from one end to the other end. That is, if a taper portion is formed on the inner surface of the sleeve of the inner surface of the fiber insertion hole to facilitate insertion of the tip end of the fiber core wire of the optical fiber into the fiber insertion hole, reflected laser light from the work piece or a mistake When the incident laser beam due to the alignment is irradiated through the fiber insertion hole, the tapered portion becomes an optical weak point and the inner surface of the fiber insertion hole may be damaged by the tapered portion. If the hole is a cylindrical hole having the same diameter from one end to the other end, an optical weak point portion with respect to laser light is not formed, and damage to the inner surface of the fiber insertion hole can be prevented.

In the invention of claim 8, the fiber insertion hole of the shielding member is a cylindrical hole having the same diameter from one end to the other end. In this case as well, similar to the invention of claim 7,
As in the case where a tapered portion is formed on the inner surface of the fiber insertion hole of the shielding member to facilitate insertion of the fiber core wire of the optical fiber, the tapered portion is not irradiated with the invading laser light and is not damaged. It is possible to prevent damage to the inner surface of the fiber insertion hole of the member.

According to the ninth aspect of the invention, a reflecting surface for reflecting the laser beam is provided on the inner surface of the fiber insertion hole of the sleeve. Further, in the invention of claim 10, a reflecting surface for reflecting the laser beam is provided on the inner surface of the fiber insertion hole of the shielding member. As a result, there is no optical weak point such as a protrusion for the laser beam on the inner surface of each fiber insertion hole, and the inner surface of the fiber insertion hole can be prevented from being damaged.

In the eleventh aspect of the present invention, a reflecting surface for reflecting the laser light is provided at least in the vicinity of the fiber insertion hole on the inner surface of the distal end wall portion of the sleeve. Even in this case, even if the laser light that has entered the sleeve strikes the inner surface of the tip wall portion, the laser light can be reflected by the reflecting surface, and the inner surface of the tip wall portion can be prevented from being damaged.

In the twelfth aspect of the invention, each of the reflecting surfaces is a total reflecting surface that totally reflects the laser light. By doing so, the laser light is totally reflected by the reflecting surface, and damage to each part can be more stably and surely prevented.

In the thirteenth aspect of the invention, the laser light is high-power laser light. As a result, the effects of the present invention are effectively exhibited.

In the invention of claim 14, any one of the above
A laser guide is provided in which one laser optical connector is attached to the end of the laser optical fiber. This makes it possible to obtain a laser guide capable of reliably preventing damage due to laser light.

[0028]

(Embodiment 1) FIG. 3 shows a laser guide G according to Embodiment 1 of the present invention. This laser guide G includes an optical fiber F for laser and a laser beam in the optical fiber F. The optical connectors C1 and C2 for lasers are attached and fixed to the respective ends on the incident side and the emitting side. Although not shown, the connector C1 on the incident side
Is connected to a laser oscillating device that outputs high-power laser light such as a YAG laser via an incident side lens portion having an incident side condensing lens, while an emitting side connector C2 faces the workpiece. Is connected to the exit side lens section thus arranged, and the exit side lens section has an exit side condensing lens.

As shown in an enlarged view in FIG. 1, the laser optical fiber F transmits high-power laser light from a laser oscillator, and comprises a core 1a and a clad 1b located around the core 1a. For example, outer diameter 200 μm to 1000
It has a silica glass fiber core wire 1 of μm and a resin jacket 2 as a protective layer coated on the fiber core wire 1 while reflecting the laser light in the core 1 a of the fiber core wire 1. To transmit.

At the end of the laser optical fiber F, an exposed portion 3 is formed by exposing the fiber core wire 1 by removing the jacket 2 from the tip side by a predetermined dimension.

On the other hand, the laser optical connectors C1 and C2 attached to the incident side and the emitting side end portions of the laser optical fiber F are the same, and as shown in the enlarged view of FIG. It has a bottomed cylindrical metal sleeve 7 having a diameter larger than the outer diameter of F. This sleeve 7
A through hole 8 is formed at the center of the tip wall portion 7a, which is the bottom wall portion, and a tip portion 9 made of sapphire or the like having high light resistance is fitted and fixed in the through hole 8. As shown in the enlarged view of FIG. 2, the tip portion 9 is of a cylindrical shape having the same length as the thickness of the distal end wall portion 7a of the sleeve 7, and the exposed portion 3 of the fiber core wire 1 is inserted therein. The fiber insertion hole 10 for opening is opened. The fiber insertion hole 10 is a cylindrical hole having the same diameter from one end to the other end, and the end of the laser optical fiber F extends from the opening on the base end side (the side opposite to the tip wall portion 7a) in the sleeve 7. The exposed portion 3 of the fiber core wire 1 and the tip portion of the jacket 2 continuous with the exposed portion 3 are fitted and inserted, and the tip portion of the exposed portion 3 is a fiber insertion hole of the tip portion 9 in the tip wall portion 7 a of the sleeve 7. The tip of the exposed part 3 is inserted into the chip 10 in a state of protruding from the outer surface of the tip part 9.

Further, a fixing portion 12 for fixing and holding the end portion of the optical fiber F with the jacket 2 is provided in the sleeve 7 at the base end side portion. This fixed part 12
Has a chuck 13 for fixing the jacket 2 of the optical fiber F located inside the sleeve 7 so as to hold it, and a chuck holding portion 14 for fixing the chuck 13 to the inner surface of the sleeve 7.

Then, the optical connectors C1 for lasers described above are provided.
A reflection surface 16 for reflecting laser light is provided in the vicinity of the fiber insertion hole 10 on the outer surface of the distal end wall portion 7a of the sleeve 7 at C2. Specifically, the outer surface of the tip part 9 is coated with a multilayer vapor deposition film to form the reflective surface 1
6 is formed. The reflecting surface 16 is preferably a total reflecting surface that totally reflects the laser light.

Therefore, in the above embodiment, when a high-power laser beam is transmitted through the optical fiber F of the laser guide G to process a workpiece, the laser beam output from the laser oscillating device is incident on the incident side lens portion. After being collected by the condenser lens of the optical fiber F, the laser light is made incident on the inside of the core 1a of the fiber core wire 1 of the optical fiber F from the incident end, and the laser light is transmitted while being reflected in the core 1a of the fiber core wire 1. The light is emitted from the emission end of the fiber F, is condensed by the condenser lens of the emission side lens unit, and then is irradiated onto the workpiece. As a result, processing such as welding and cutting is performed on the processed portion.

If the work piece is made of a material of a type such as aluminum or galvanized metal that is easily reflected, part of the laser light emitted from the optical fiber F is reflected by the work piece, and The reflected laser light passes through the condenser lens and returns to the emission side connector C2 side, and hits the tip portion 9 (near the fiber insertion hole 10) of the distal end wall portion 7a of the sleeve 7. However, since the reflection surface 16 of the laser light is formed on the outer surface of the tip portion 9 by the coating process with the multilayer vapor deposition film, even if the reflection laser light hits the tip portion 9, the reflection laser light is reflected by the reflection surface 16. It is reflected and diffuses. As a result, the tip portion 9 of the sleeve 7
It is possible to surely prevent the damage.

On the other hand, in the incident side optical connector C1 at the incident side end portion of the laser guide G (optical fiber F), if there is a misalignment of the optical axis with the lens portion on the side of the laser oscillator, it will occur. The incident laser light focused by the condenser lens of the lens portion strikes the outer surface of the tip portion 9 of the sleeve 7, but even in that case, the incident laser light is reflected by the reflecting surface 16 provided on the outer surface of the tip portion 9. Spread. Therefore, in this case as well, damage to the tip portion 9 of the sleeve 7 can be reliably prevented.

The laser light reflecting surface 16 on the outer surface of the tip portion 9 of the tip wall portion 7a of the sleeve 7 of each of the connectors C1 and C2 is formed by a coating process in which a multilayer vapor deposition film is formed on the outer surface of the tip portion 9. Because it is formed
The reflective surface 16 can be easily formed on the chip portion 9.

Furthermore, since the fiber insertion hole 10 of the tip portion 9 of the sleeve 7 is a cylindrical hole having the same diameter from one end to the other end, the following operational effects can be obtained. That is, when the end portion of the optical fiber F is inserted from the base end side opening of the bottomed cylindrical sleeve 7, the tip end of the fiber core wire 1 is located at the tip wall portion which is the bottom wall portion of the sleeve 7. In order to facilitate insertion into the insertion hole 10, a tapered portion 10a may be formed on the inner surface side of the sleeve 7 on the inner surface of the fiber insertion hole 10 as shown by the phantom line in FIG. When the reflected laser light or the incident laser light due to misalignment is irradiated through the fiber insertion hole 10 of the chip portion 9, the tapered portion 10a becomes an optical weak point portion, and the inner surface of the fiber insertion hole 10 is formed by the tapered portion 10a. There is a risk of damage. On the other hand, in this embodiment, since the fiber insertion hole 10 is formed of a cylindrical hole having the same diameter from one end to the other end, the optical weak point portion for the laser beam as described above is not formed, and the fiber insertion hole is not formed. 10 It is possible to prevent damage to the inner surface.

(Second Embodiment) FIG. 4 shows a second embodiment of the present invention.
(In each of the following embodiments, the same parts as those in FIGS. 1 to 3 are designated by the same reference numerals and detailed description thereof is omitted), and penetrates into the sleeve 7 through the fiber insertion hole 10. It is designed to deal with laser light.

That is, in this embodiment, in the sleeve 7 of each of the connectors C1 and C2 on the incident side and the output side, one shield made of metal such as brass is provided in the exposed portion 3 of the fiber core wire 1 near the jacket 2. The member 18 is fitted. The shielding member 18 is a disk-shaped member, and at the center position thereof is the same as the fiber insertion hole 10 in the tip portion 9 of the distal end wall portion 7a of the sleeve 7, that is, a cylindrical hole having the same diameter from one end to the other end. A fiber insertion hole 19 made of is formed so as to penetrate therethrough, and the fiber core wire 1 is inserted in the fiber insertion hole 19.
The exposed portion 3 is inserted, and in this state, the shielding member 18 is fitted and inserted in the sleeve 7, and the outer peripheral edge portion is fixedly supported on the inner peripheral surface of the sleeve 7.

Further, on both surfaces of the shielding member 18, on the tip side surface of the tip portion 9 opposite to the fiber insertion hole 10, a reflection surface 20 for reflecting the laser beam is plated with gold or the like like the outer surface of the tip portion 9. It is formed by. Other configurations are the same as those in the first embodiment.

Therefore, in this embodiment, the reflected laser light from the workpiece and the incident laser light due to misalignment are, as shown in FIG. 5, connectors C1 and C.
2, even if it penetrates into the sleeve 7 through the gap between the fiber insertion hole 10 of the sleeve 7 and the fiber core wire 1 of the optical fiber F inserted therein or through the clad 1b of the fiber core wire 1, The invading laser light is shielded by the shielding member 18 which is inserted between the fiber insertion hole 10 of the sleeve 7 and the jacket 2 of the optical fiber F and which is inserted into the exposed portion 3 of the fiber core wire 1. Therefore, the incident laser beam does not hit the jacket 2 and is damaged, and the jacket 2 of the optical fiber F can be reliably prevented from being damaged.

Further, since the laser light reflecting surface 20 is formed on the tip side surface of the shielding member 18, even if the laser light entering the sleeve 7 from the fiber insertion hole 10 hits the shielding member 18, the laser light will be emitted. Is reflected by the reflecting surface 20 of the shielding member 18 and diffuses. Therefore, the shielding member 1
The damage to the jacket 8 of the optical fiber F can be stably and reliably prevented by preventing the damage of 8 itself.

Further, the fiber insertion hole 1 of the shielding member 18
Since 9 is a cylindrical hole having the same diameter from one end to the other end, the inner surface of the fiber insertion hole 19 for facilitating insertion of the fiber core wire 1 of the optical fiber F is similar to the fiber insertion hole 10 of the chip portion 9 described above. Unlike the case where the tapered portion is formed in the above, the tapered portion is not irradiated with the invading laser light and is not damaged, and damage to the inner surface of the fiber insertion hole 19 of the shielding member 18 can be prevented.

In the second embodiment, the shielding member 1
8 is not limited to one, and a plurality of shielding members 18 may be arranged side by side on the exposed portion 3 of the fiber core wire 1. In that case, the intervals between the plurality of shielding members 18 are not limited, and all the shielding members 18 may be arranged in an overlapping manner.

(Other Embodiments) The present invention is not limited to the above-described two embodiments and includes various other embodiments. For example, in each of the above-described embodiments, the reflection surface 16 of the laser beam is formed by the coating process in which a multilayer vapor deposition film is formed on the outer surface of the chip portion 9. However, in addition to this, the reflection surface 16 may be formed by plating. Alternatively, the tip portion 9 itself may be made of a material such as gold or aluminum having high reflectance and light resistance, and the outer surface thereof may be formed as a total reflection surface 16 by polishing or the like. . Further, the shielding member 18 itself is made of a material having a high reflectance and a high light resistance, and the tip side surface thereof is polished or the like to form the reflection surface 20.
It can also be formed.

In each of the above embodiments, the tip portion 9 is attached to the tip wall portion 7a of the sleeve 7, but the fiber insertion hole 10 may be formed through the tip wall portion 7a of the sleeve 7. In that case, the tip wall portion 7 of the sleeve 7
a near the fiber insertion hole 10 on the outer surface or the tip wall portion 7a
The laser light reflecting surface 16 may be provided on the entire outer surface, and the same effects as those of the above-described embodiment can be obtained.

Further, in the sleeve 7 of each of the connectors C1 and C2, the inner surface of the fiber insertion hole 10 of the chip portion 9 or the inner surface of the fiber insertion hole 19 of the shielding member 18 may be formed as a reflection surface of laser light. In this way, the fiber insertion hole 1
Optical weak points such as protrusions against the laser light are eliminated on the inner surfaces of the fibers 0 and 19, and damage to the inner surfaces of the fiber insertion holes 10 and 19 can be prevented.

Furthermore, in the sleeve 7 of each of the connectors C1 and C2, the inner surface of the tip portion 9 of the distal end wall portion 7a (near the fiber insertion hole 10 on the inner surface of the distal end wall portion 7a of the sleeve 7).
Alternatively, a reflecting surface for laser light can be formed on the entire inner surface of the tip wall portion 7a, and even if the laser light entering the sleeve 7 through the fiber insertion hole 10 hits the inner surface of the tip wall portion 7a, Reflected by the reflective surface, the tip wall 7
a It is possible to prevent the inner surface from being damaged.

In the above embodiment, the optical connectors C1 and C2 connected to both ends of the optical fiber F are the same, but the optical connectors may be different from each other. Furthermore, it goes without saying that the present invention can be applied to a laser guide in which an optical connector is connected to only one end of the optical fiber F.

[0051]

EXAMPLE Next, a concrete example will be described. As in the second embodiment (see FIG. 4), the tip wall 7a of the sleeve 7 of the connectors C1 and C2 has a tip portion 9 made of sapphire. And place SiO on its outer surface
A _second layer and HFO ₂ layer was formed a reflecting surface 16 made of total reflection coating layer is deposited by vapor deposition alternately multiple layers. In addition, one shield member 18 made of brass is provided in the sleeve 7.
Was placed so as to pass through the exposed portion 3 of the optical fiber F, and the reflecting surface 20 was formed on the entire surface on the tip end side by gold plating.

Using the laser guide G in which the connectors C1 and C2 and the optical fiber F having such a structure are combined,
When aluminum was processed by a YAG laser having an output of 2.7 kW, the jacket 9 of the optical fiber F in the chip portion 9 of the connectors C1 and C2 and the sleeve 7 was not damaged. From this, it is understood that the effect of the present invention is effective.

[0053]

As described above, according to the invention of claim 1, as a laser optical connector attached to the end of the fiber for transmitting laser light, the protective layer is removed from the tip to expose the fiber core. A sleeve having an end portion of an optical fiber formed with a fiber insertion hole inserted into the exposed portion and the protective layer, and a fiber insertion hole for inserting the tip of the exposed portion of the fiber core wire into the tip wall portion; And a fixing portion for fixing and holding the end portion of the optical fiber with a protective layer, and by providing a reflecting surface of the laser light at least in the vicinity of the fiber insertion hole on the outer surface of the distal end wall portion of the sleeve, after emitting from the optical fiber The reflected laser light reflected by the work piece or the incident laser light due to the misalignment of the optical axis between the optical connector at the incident side end of the optical fiber and the laser oscillator side is reflected by the connector. Even it hits the fiber insertion hole near the over blanking the front end wall portion, so that the laser light can be diffuse reflected by the reflecting surface, thus to reliably prevent damage to the fiber insertion hole near the sleeve.

According to a second aspect of the present invention, at least one shielding member is inserted into the sleeve of the optical connector for laser as in the first aspect of the invention, and the exposed portion of the fiber core wire is inserted into the fiber insertion hole. By providing the protective layer, reflected laser light and incident laser light that enter the sleeve through the gap between the fiber insertion hole of the sleeve and the fiber core of the optical fiber, the clad of the fiber core, etc. The contact with the shield can be shielded by the shield member, and damage to the protective layer of the optical fiber in the sleeve can be reliably prevented.

According to the invention of claim 3, in the optical connector for laser of claim 1, at least one shielding member is provided in the sleeve with the exposed portion of the fiber core wire being inserted into the fiber insertion hole. As a result, the actions and effects of the inventions of claims 1 and 2 are synergistically obtained.

In the invention of claim 4, a tip portion having a fiber insertion hole is provided on the tip wall portion of the sleeve, and a reflection surface is formed on the outer surface of the tip portion. Further, in the invention of claim 5, a reflective surface is formed on the outer surface of the same chip portion by a coating treatment. According to these inventions, the structure of the reflecting surface can be embodied.

According to the sixth aspect of the present invention, since the tip side surface of the shielding member is provided on the reflecting surface of the laser beam, the shielding member itself is not damaged by the laser beam entering the sleeve through the fiber insertion hole. Therefore, damage to the protective layer of the optical fiber can be stably and reliably prevented.

In the invention of claim 7, the fiber insertion hole of the sleeve is a cylindrical hole having the same diameter from one end to the other end. Further, in the invention of claim 8, the fiber insertion hole of the shielding member is a cylindrical hole having the same diameter from one end to the other end. According to these inventions, it is possible to prevent the inner surfaces of the fiber insertion hole of the sleeve or the shielding member from being irradiated with the laser beam and being damaged.

According to the ninth aspect of the invention, the laser light reflecting surface is provided on the inner surface of the fiber insertion hole of the sleeve. Further, according to the invention of claim 10, a reflection surface of the laser beam is provided on the inner surface of the fiber insertion hole of the shielding member. As a result, it is possible to eliminate the optical weak points such as protrusions for the laser light on the inner surface of the fiber insertion hole, and prevent the inner surface of the fiber insertion hole from being damaged.

According to the eleventh aspect of the present invention, the reflecting surface for reflecting the laser light is provided at least in the vicinity of the fiber insertion hole on the inner surface of the tip wall portion of the sleeve, so that the laser light entering the sleeve is covered by the inner surface of the tip wall portion. Even if you hit
The laser light can be reflected by the reflecting surface to prevent the inner surface of the tip wall portion from being damaged.

According to the twelfth aspect of the present invention, since each reflection surface is a total reflection surface that totally reflects the laser light, the laser light can be totally reflected by the reflection surface, and the damage to each part can be more stably and reliably performed. Can be prevented.

According to the thirteenth aspect of the invention, since the laser light is a high-power laser light, the effect of the present invention is effectively exhibited.

According to the fourteenth aspect of the present invention, each of the laser optical connectors is attached to the end of the laser optical fiber to provide a laser guide, so that a laser guide capable of reliably preventing damage due to laser light is provided. can get.

[Brief description of drawings]

FIG. 1 is a sectional view showing a laser optical connector according to a first embodiment of the present invention.

FIG. 2 is an enlarged sectional view showing a fiber insertion hole of a sleeve and its vicinity.

FIG. 3 is a diagram showing an overall configuration of a laser guide.

FIG. 4 is a view corresponding to FIG. 1 showing a second embodiment.

FIG. 5 is a cross-sectional view showing a state where laser light enters a sleeve through a fiber insertion hole.

[Explanation of symbols] G laser guide F optical fiber C1, C2 laser optical connector 1 fiber core 2 jacket (protective layer) 3 exposed parts 7 sleeve 7a Tip wall 9 chips 10 Fiber insertion hole 12 Fixed part 16 reflective surface 18 Shielding member 19 Fiber insertion hole 20 reflective surface

Continued front page    (72) Inventor Takeshi Satake             4-3 Ikejiri, Itami City, Hyogo Prefecture Mitsubishi Electric Cable             Industrial Co., Ltd. Itami Works (72) Inventor Motohiko Yamazaki             4-3 Ikejiri, Itami City, Hyogo Prefecture Mitsubishi Electric Cable             Industrial Co., Ltd. Itami Works (72) Inventor Koji Kimura             4-3 Ikejiri, Itami City, Hyogo Prefecture Mitsubishi Electric Cable             Industrial Co., Ltd. Itami Works (72) Inventor Kazuki Kuba             2-3 2-3 Marunouchi, Chiyoda-ku, Tokyo             Inside Ryo Electric Co., Ltd. (72) Inventor Takafumi Kawai             2-3 2-3 Marunouchi, Chiyoda-ku, Tokyo             Inside Ryo Electric Co., Ltd. (72) Inventor Shuichi Fujikawa             2-3 2-3 Marunouchi, Chiyoda-ku, Tokyo             Inside Ryo Electric Co., Ltd. (72) Inventor Masaaki Seguchi             2-3 2-3 Marunouchi, Chiyoda-ku, Tokyo             Inside Ryo Electric Co., Ltd. (72) Inventor Takefumi Shiga             1 Toyota Town, Toyota City, Aichi Prefecture Toyota Auto             Car Co., Ltd. (72) Inventor Masato Shirai             1 Toyota Town, Toyota City, Aichi Prefecture Toyota Auto             Car Co., Ltd. (72) Inventor Yoichiro Furumata             1 Toyota Town, Toyota City, Aichi Prefecture Toyota Auto             Car Co., Ltd. F-term (reference) 2H037 AA02 AA03 AA04 BA06 DA04                 4E068 CE08

Claims (14)

[Claims] 1. An optical connector for a laser, which comprises a fiber core wire composed of a core and a clad covered with a protective layer and is attached to an end portion of a laser optical fiber for transmitting a laser beam, wherein the protective layer is provided from a tip end. An end portion of the optical fiber from which the exposed portion of the fiber core wire is removed and is fitted and inserted across the exposed portion and the protective layer, and a fiber insertion hole through which the front end portion of the exposed portion of the fiber core wire is inserted A sleeve having an opening, and a fixing portion for fixing and holding the end portion of the optical fiber with a protective layer in the sleeve, and reflects the laser light at least near the fiber insertion hole on the outer surface of the distal end wall portion of the sleeve. An optical connector for a laser, which is provided with a reflecting surface. 2. A laser optical connector which is formed by coating a fiber core wire composed of a core and a clad with a protective layer and is attached to an end portion of a laser optical fiber for transmitting a laser beam, wherein the protective layer is provided from a tip end. An end portion of the optical fiber from which the exposed portion of the fiber core wire is removed and is fitted and inserted across the exposed portion and the protective layer, and a fiber insertion hole through which the front end portion of the exposed portion of the fiber core wire is inserted And a fixing portion for fixing and holding an end portion of the optical fiber with a protective layer in the sleeve, and at least one shielding member having a fiber insertion hole is provided in the sleeve. An optical connector for a laser, characterized in that it is provided with an exposed portion of a fiber core being inserted into the optical fiber. 3. The laser optical connector according to claim 1, wherein at least one shielding member having a fiber insertion hole is provided in the sleeve in a state where the exposed portion of the fiber core wire is inserted into the fiber insertion hole. Optical connector for laser, which is characterized by 4. The laser optical connector according to claim 1 or 3, wherein a tip portion having a fiber insertion hole is provided on a tip wall portion of the sleeve, and a reflecting surface is formed on an outer surface of the tip portion. An optical connector for laser, which is characterized in that 5. The laser optical connector according to claim 1 or 3, wherein a tip portion having a fiber insertion hole is provided on a tip wall portion of the sleeve, and a reflection surface is formed on the outer surface of the tip portion by a coating process. Optical connector for laser, which is characterized by 6. The laser optical connector according to claim 2 or 3, wherein the tip side surface of the shielding member is provided on a reflecting surface that reflects laser light. 7. The optical connector for laser according to claim 1, wherein the fiber insertion hole of the sleeve is a cylindrical hole having the same diameter from one end to the other end. 8. The laser optical connector according to claim 2, 3 or 6, wherein the fiber insertion hole of the shielding member is a cylindrical hole having the same diameter from one end to the other end. 9. The laser optical connector according to claim 1, 2, 4, 5, or 7, wherein a reflection surface for reflecting laser light is provided on the inner surface of the fiber insertion hole of the sleeve. Optical connector. 10. The laser optical connector according to claim 2, 3, 6 or 8, wherein a reflection surface for reflecting laser light is provided on an inner surface of the fiber insertion hole of the shielding member. connector. 11. The laser optical connector according to claim 1, wherein a reflection surface for reflecting laser light is provided at least in the vicinity of the fiber insertion hole on the inner surface of the distal end wall portion of the sleeve. Optical connector for laser. 12. The optical connector for lasers according to claim 1, wherein the reflection surface is a total reflection surface that totally reflects the laser light. 13. The optical connector for lasers according to claim 1, wherein the laser light is high-power laser light. 14. A laser guide comprising the optical connector for laser according to claim 1 attached to an end of an optical fiber for laser.