BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic of one channel of a non-fiber optic system according to the present invention;
FIG. 2 is a schematic of one channel of a fiber coupled system according to the present invention;
FIG. 3 is a schematic of one channel of a non-fiber system using polarization beam combiners according to the present invention;
FIG. 4 is a schematic of one channel of a fiber coupled system using polarization beam combiners according to the present invention;
FIG. 5 is a ray trace and screen shots of spot sizes measured by two detectors;
FIG. 6 is a schematic of one channel for a serial exposure mode according to the present invention;
FIG. 7 is a schematic of one channel using two diodes having the same wavelength with fiber optics having different dimensions;
FIG. 8 is a schematic of the embodiment shown in FIG. 7 using diodes which emit at different wavelengths;
FIG. 9 is a schematic of one channel of the present invention with the distal end of the fibers arranged in different object planes;
FIG. 10 is a schematic of a system for measuring the relative shift in the image plane V, versus the fiber position in the object plane U;
FIG. 11 is a graph showing relative shift in image plane versus fiber position U, in the object plane;
FIG. 12 is an embodiment of the present invention incorporating a glass plate of thickness D and index of refraction n;
FIG. 13 is an embodiment of the present invention incorporating a glass plate constructed from several zones, each having a different thickness and different or same index of refraction;
FIG. 14 is an embodiment of the present invention incorporating a glass plate which has a variable profile of the index of refraction along the Y direction;
FIG. 15 is a schematic showing an embodiment for confocal and auto-focus measurements useful in a diagnostics system;
FIG. 16 shows conversion of a Gaussian beam profile to two types of top hat profiles by using diffractive elements;
FIG. 17 shows a cross-section of a specific case where optical fibers are aligned in two V-grooves; and
FIG. 18 is an expanded view of one of the V-grooves shown in FIG. 17.
DETAILED DESCRIPTION OF THE INVENTION
The present invention suggests several methods by which the laser diode light is controlled in order to enhance the direct engraving and ablating effect. Referring to FIG. 1, the invention is described by the schemes shown for the specific case of two laser diodes 10, 12 that emit in two different wavelengths. By using laser diodes which emit at different wavelengths, and by controlling the dispersion of the imaging lens 16, the focus points 18, 20 at the different wavelengths will be shifted one relative to each other.
FIG. 2 describes the same idea as FIG. 1 for the case of fiber coupled diodes. The two different wavelengths are combined into one fiber using a fiber optic coupler 26 instead of the beam combiner 22.
The light emitted from laser diodes is highly polarized. Therefore, by using a polarization beam combiner 24, shown in FIG. 3, the power of two diodes that emit the same wavelength 10a, 10b can be combined into one path. Doing so the power of each wavelength is doubled and the overall power that impinges on the plate can be increased by four times. Polarization beam combiners are well known elements used in the optical field to couple light sources that have different configurations. Polarization beam combiners are available in both free space and fiber (mainly for single mode fibers) coupled configurations.
FIG. 4 shows the same general concept as FIG. 3 for the case of fiber coupled diodes in an embodiment using two different wavelengths. The power of two fiber coupled diodes that emit the same wavelength 10a, 10b is first combined into one fiber by using a polarization fiber-optic combiner 27. Two additional diodes 10c, 10d, which emit a second wavelength are combined into one path.
In order to roughly check and present the concept a simulation, shown in FIG. 5, using a specific imaging lens and two diodes which emit at 800 nm and 970 nm, was carried out. The results show the ray trace and the spot size as measured by two detectors. The detectors are located at the two focal points, which are shifted in approximately 100 micron relative to each other. The imaging lens can of course be designed in order to achieve a desired shift.
FIG. 6 shows laser diodes 30a, 30b with different wavelengths located adjacent to each other. In general, the optical head (not shown) moves along the plate, in the direction indicated by arrow 31. First, laser diode 30b is activated and just then the laser diode 30a, i.e. when it reached the same pixel which was already exposed by laser diode 30b. The embodiment described uses fiber coupled diodes. The description is just for two out of n channels. The same general idea can of course be implemented, with no fibers.
Optical fibers 33a and 33b with different core diameters can be assembled on the same V-groove 35, as shown in FIG. 7. This can be implemented for the same or different wavelengths. This way, by using only one imaging lens 37 one can get spots of two sizes. The figures show an example for two laser diodes 32a and 32b of the same wavelength. If optical fiber 33b is a 40 micron fiber and optical fiber 33a is a 100 micron fiber, then by using a 1×2 imaging lens 37 one gets a 20 micron spot 40b and a 50 micron spot 40a.
FIG. 8 shows the same concept, but now the laser diodes 41a and 41b emit at different wavelengths. Spots of different diameters 42a and 42b respectively are achieved at different locations.
In FIG. 9, the distal tips of optical fibers 43a and 43b are assembled in the V-groove 44 in different object planes 45 and 46 respectively relative to each other. As a result, the image planes 47 and 48 of the different fiber tips respectively will be shifted one relative to the other. FIG. 9 shows the effect just for two fibers. The optical fibers can be identical, or different, for example with different core diameters. Fibers can emit radiation at the same or different wavelengths.
In any one of the embodiments of FIGS. 6 through 9, the optical radiation guided in the fiber can be in a filled or an underfilled state. In general, the laser diodes can be temporally modulated relative to each other in order to get different effects on the direct engraving plate.
FIG. 10 describes an example of a specific measurement system in which the image position shift was measured.
The graph in FIG. 11 shows the relative shift in the image position as a function of the position U, of the distal tip of the fiber, as measured by the system of FIG. 10. The shift in image position V, was found by moving the position of the microscope lens in order to find the smallest spot. A laser beam analyzer was used to measure and define a spot that includes 95% of the laser beam energy.
For this specific case of using a telecentric imaging lens with a magnification of 2, it can be seen that moving the distal tip of the fiber in the object plane X mm results in a shift of 0.508 X mm in the image position. For example, moving the distal tip of the fiber 0.2 mm, from U=40 to U=40.2, causes the image to move by an absolute relative distance of 0.1 mm.
As shown in FIG. 12, a glass plate 50 of thickness D placed between the distal tip of the fiber 52 and the imaging lens 54, will cause the image plane to shift from image plane 47 to 48. The shift V in the position of the image plane is a function of the thickness D of the plate and its index of refraction n. The schematic presents the effect of such a glass plate for the specific case of a single laser diode 55. The solid rays describe the case when no plate is used and in which the rays are focused in image plane 47. The dashed rays describe the case when a plate is used and in which the focus is shifted to image plane 48. When a multi laser source constructed from different wavelengths is used the shift V will be a function of the wavelength due to the fact that the index of refraction n, is a function of the wavelength.
The glass plate can be constructed from several zones, each having a different thickness and different or same index of refraction as depicted in FIG. 13. Such a structure enables moving and adjusting the glass plate in front of the fiber tips in order to get a required shift.
The glass plate can also have a variable profile of the index of refraction that changes along the Y direction. This form of the glass plate is shown in FIG. 14. Such a structure enables to move and adjust the right zone of the glass plate in front of the fiber tips in order to get a required shift. The glass plate may also be inserted between the imaging lens and the imaged surface.
An example of the concept is shown in FIG. 15. Optical detectors 60a and 60b, are optically coupled to laser diodes 62a, 62b by fiber optic couplers 61a and 61b and optical fibers 63a through 63d, respectively. The laser radiation that impinges on the printing plate is partially reflected backwards and detected by optical detectors 60a and 60b. The signal at optical detector 60a, V1, and the signal at optical detector 60b, V2, are proportional to the position of the printing plate. When the plate is in position A the signal at optical detector 60a will be at its maximum value, and when the plate is in position B, the signal at optical detector 60b will be at its maximum value. Hence, signals V1 and V2 can be used to adjust the imaging lens at a desired distance relative to the position of the printing plate. Furthermore, the signals V1 and V2 can be used to inspect and diagnose the printing plate after or during the exposure to the laser beam.
When a single mode diode is used, the Gaussian profile of the beam can be converted, utilizing diffractive optic elements, to be top hat, as depicted in FIG. 16 Such diffractive elements are made by several companies, including: www.holoor.co.il/website/data/index.html.
The light source described by FIGS. 1-16 can be a diode laser and/or a fiber coupled diode laser. The different configurations in which the fibers are aligned relative to each other described by FIGS. 1-16 can be done relative to the slow and/or fast axis of the printing drum (the slow and fast axis are well known parameters to any one skilled in the printing art).
The fibers can be aligned in space in any configuration relative to each other; for example, in a mechanical support, such as a V-groove 65, shown in FIGS. 17 and 18. The fibers may be aligned one adjacent to the other and/or one above the other, where two or more V-grooves are aligned one on top of the other in a sandwich configuration. The specific case of a sandwich configuration can be seen in FIG. 17.
By using diodes at different wavelengths several advantages can be obtained for direct engraving. By a proper optical design the depth of focus can be increased while keeping a relative good spot size which will fit the direct engraving quality.
The diodes can be spatially (by using fibers with different core diameters, or by positioning the distal tips of the fibers at different object planes) and/or temporally modulated relative to each other in order to get different effects on the direct engraving plate. For example, by initiating the first diode before the second diode, etc.
When using laser diodes which emit light at different wavelengths, the multi color light source can be tailored to the special optical and thermal characteristics of a direct engraving printing plate, such as the printing plate described in commonly-assigned copending U.S. patent application Ser. No. 11/353,217.
The advantages of the present invention are:
Increasing both the power and depth of focus while keeping a relatively good spot size which will be adequate for the quality needed for direct engraving.
The lasers can be temporally modulated, simultaneously or relative to each other in order to get a better thermal effect on special engraving plates.
Direct modulation of the lasers does not require external modulation.
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
Parts List
10 laser diode
10
a wavelength λ2 P polarization
10
b wavelength λ2 S polarization
10
c wavelength λ1 P polarization
10
d wavelength λ1 S polarization
12 laser diode
16 imaging lens
18 focus point
20 focus point
22 beam combiner
24 polarization beam combiner
26 fiber optic coupler
27 polarization fiber-optic combiner
30
a laser diode
30
b laser diode
31 direction of head movement
32
a laser diode
32
b laser diode
33
a optical fiber
33
b optical fiber
35 V-groove
37 imaging lens
40
a spot with 50 microns diameter
40
b spot with 20 microns diameter
41
a laser diode
41
b laser diode
42
a spot with 50 microns diameter
42
b spot with 20 microns diameter
43
a optical fiber
43
b optical fiber
44 V-groove
45 object plane
46 object plane
47 image plane
48 image plane
50 glass plate
52 optical fiber
54 imaging lens
55 laser diode
60
a optical detector
60
b optical detector
61
a fiber optic coupler
61
b fiber optic coupler
62
a laser diode
62
b laser diode
63
a optical fiber
63
b optical fiber
63
c optical fiber
63
d optical fiber
65 V-groove