Optical waveguides – Noncyclindrical or nonplanar shaped waveguide
Reexamination Certificate
2003-06-27
2004-11-16
Lee, John R. (Department: 2881)
Optical waveguides
Noncyclindrical or nonplanar shaped waveguide
C385S024000, C385S031000, C385S033000, C385S049000, C385S088000, C385S105000, C385S106000, C385S112000, C385S113000, C385S115000, C385S116000, C385S119000, C385S120000, C385S121000, C385S123000, C385S129000, C385S130000, C385S131000, C385S132000, C359S204200, C359S364000, C250S227310, C250S227320
Reexamination Certificate
active
06819861
ABSTRACT:
INCORPORATION BY REFERENCE
This application is based on and claims priority under 35 U.S.C. sotn. 119 with respect to Japanese Applications No. 2002-188487 filed on Jun. 27, 2002 and No. 2002-221596 filed on Jul. 30, 2002, the entire contents of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a laminated optical waveguide array, a beam collecting device and a laser emission device for collecting laser beams to a target position on an article to be processed.
2. Discussion of the Related Art
FIG. 16
shows a general construction of a semiconductor laser beam collecting device known as prior art. The semiconductor laser beam (hereafter referred simply as “laser beam”)
2
is emitted from a beam emitting part
12
on an active layer of a semiconductor laser (such as a laser diode or the like) and takes the form of an elliptical in the section normal to the direction in which the laser beam
2
travels. The laser beam
2
of the elliptical form has a fast axis direction and a slow axis direction. The longer the elliptical form is distanced from the beam emitting part
12
, the larger it becomes. There has been known a semiconductor laser beam collecting device of the type wherein laser beams emitted from a plurality of beam emitting parts which are arranged in a second-order matrix extending in the fast axis direction and in the slow axis direction are collected by optical fibers of a fewer number to reinforce the output of the laser beams.
For example, where the semiconductor lasers are to be employed as a power source for a laser machining apparatus or a laser material processing apparatus, it must be of a high power. The laser beam emitted from a single beam emitting part is weak in power strength. Thus, a group of lenses are used to collect laser beams emitted from a plurality of beam emitting parts thereby to strengthen the output of the laser beams.
Japanese unexamined, published patent application No. 2000-98191 discloses a semiconductor laser beam collecting device shown in FIG.
16
. In the application, it is proposed to collect laser beams to optical fibers thereby to strengthen the beam output power by utilizing a group of lenses and the optical fibers
30
and arranging a fast axis direction collimation lens array
70
, a fast axis direction collective lens
80
and a slow axis direction collective lens
90
, in turn within a very short space from the beam emitting parts
12
to the optical fibers
30
.
In order that laser beams emitted from semiconductor laser emitting parts are collected efficiently to optical fibers thereby to strengthen the output power of the laser beams, it is necessary to gain the density of the beams by entering the beams from many numbers of the emitting parts into much finer optical fibers and to enter the beams efficiently into the optical fibers by entering the beams into the incidence surfaces or surfaces of the optical fibers at a smaller or gentle incident angle, namely, at an angle as close as the right angle to the incidence surfaces without reflecting the entered laser beams outside.
The laser beams coming from the emitting parts
12
advance as they spread in the fast axis direction as well as in the slow axis direction. For collection of the laser beams which advance as spreading, the lenses used therein and the arrangement of the same are to be quite highly precise.
In the semiconductor laser collecting device known heretofore (e.g., from the aforementioned Japanese patent application No. 2000-981919), the emitting parts are arranged with a relatively wide space in the fast axis direction, and correcting the beams in that direction is carried out with the fast axis direction collecting lens
80
once they are transformed with the fast axis direction collimation lens array
70
into parallel beams. On the other hand, the emitting parts
12
are arranged with a relatively narrow space in the slow axis direction, which requires that the lenses used be very small in diameter and difficult to arrange. Thus, collecting the beams in the slow axis direction is carried out with the slow axis direction collecting lens array
90
without transforming the beams into those parallel.
That is, in the prior art device mentioned above, the space between the slow axis beam collective lens array
90
and the emitting parts
12
is short, e.g., several millimeters at most. It is therefore difficult to arrange the fast axis direction collimation lens array
70
and the slow axis direction beam collective lens array
90
properly within the short space. The optical fibers
30
are caused to be arranged within a short distance from the emitting parts
12
. Thus, where the incident angle (&thgr;
outx
) in the fast axis direction is set small, the number of the laser beams which can be collected in the fast axis direction is made small, so that it cannot be practiced to obtain high power laser beams from a large number of optical fibers for use in laser machining.
SUMMARY OF THE INVENTION
It is therefore a primary object of the present invention to provide a laminated optical waveguide array, a beam collecting device and a laser emission device capable of collecting many numbers of laser beams for a higher power output.
Another object of the present invention is to provide a laminated optical waveguide array, a beam collecting device and a laser emission device capable of restraining laser beams from shining therethrough thereby to enhance the laser collecting efficiency.
Briefly, according to the present invention, there is provided a laminated optical waveguide array comprising: a plurality of plate-like optical waveguides made of a material having a predetermined refractive index; and a plurality of spacer members having a lower refractive index than that of the optical waveguides and arranged alternately with the optical waveguides.
With this configuration, a spacer member is interposed between two adjoining optical waveguides, so that the dimension in the space between the adjoining optical waveguides can be set precisely and easily. In particular, since the spacer members are made of a material having a lower refractive index than that of the optical waveguides, the laser beams traveling within the optical waveguides is restrained from coming therethrough, so that th beam collecting efficiency can be enhanced. Preferably, optical fibers may be utilized as the spacer means as described in one form of the embodiments. Since optical fibers in the market have various outer diameters machined precisely and are easily available. Therefore, by selecting the optical fibers properly, the spacer members for the optical waveguides can be made easily and at a lower cost. Spacer balls and plate members may be utilized as the spacer member as described in other forms of the embodiments.
In another aspect of the present invention, there is provided a laser emission device comprising: a semiconductor laser array having a plurality of laser emitting parts which are arranged in a fast axis direction as well as in a slow axis direction each for emitting a laser beam of an elliptical cross-section which spreads in the fast and slow axis directions as it travels; a plurality of optical fibers; a collective lens; and a laminated optical waveguide array composed of a plurality of plate-like optical waveguides made of a material having a predetermined refractive index and a plurality of spacer members having a lower refractive index than that of the optical waveguides and arranged alternately with the optical waveguides. The waveguide array is arranged between the semiconductor laser array and the plurality of optical fibers for collecting laser beams emitted from plural laser emitting parts of a group separated from other groups in the slow axis direction, to one of the optical fibers aligned thereto. The collective lens further collects the collected laser beams from all of the optical fibers and concentrates them to a target position.
With this configuration, a plurality of laser beams em
Katoh Yoshinobu
Niino Yasuo
Ota Hiromichi
Lee John R.
Souw Bernard E.
Toyoda Koki Kabushiki Kaisha
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