Incremental printing of symbolic information – Light or beam marking apparatus or processes – Scan of light
Reexamination Certificate
1999-01-21
2001-08-14
Le, N. (Department: 2861)
Incremental printing of symbolic information
Light or beam marking apparatus or processes
Scan of light
C347S246000, C347S237000, C385S126000
Reexamination Certificate
active
06275250
ABSTRACT:
FIELD OF THE INVENTION
This invention relates generally to a laser marking system and more particularly to fiber laser marking systems operated cw or pulsed for marking surfaces of objects with information or data, hereinafter referred to as “indicia” which includes, for example, alphanumeric information, letters, words, personal or company logos, tradenames, trademarks, data or batch codes, numbers, symbols, patterns, article coding or identification, personalized signatures, and the like.
BACKGROUND OF THE INVENTION
Laser marking systems have been in existence for at least two decades or more for marking indicia on surfaces of articles. A major application of laser marking of articles is the identification or marking of an article, product or a product package, particularly with respect to high volume manufacturing lines where the desire is to mark the article or package “on-the-fly” as the same passes through a marking station. This type of marking provides data about the product, such as, date of manufacture, shelf life, factory origin, model and/or serial number, product tracking and the like. The use of lasers to provide marking indicia is preferred since it is not significantly physically intrusive, does not generally affect the integrity of the article or product or its packaging, and the marked indicia is not easily removable.
An example of traditional laser marking systems for these above mentioned applications are cw or pulsed CO
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lasers and yttrium aluminum garnet (YAG), e.g., Nd:YAG lasers where the marking is accomplished by the heat of the applied laser beam. The wavelengths of the pulses produced by these systems are within the visible or infrared spectrum. Indicia to be marked is formed by using a mask through which the laser beam passes or by a focused laser beam which is moved or scanned to produce the desired indicia. Such lasers are also employed for engraving, soldering and welding wherein, in the case of marking, the surface layer of the material is melted, ablated or vaporized to produce discernible indicia. Also, this type of article marking may be accomplished by use of a chemical reaction at the article surface to be marked where certain coating agents on the surface of the article, which may be visually transparent, undergo a visible contrast change under the influence of a laser beam or laser pulses.
CO
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lasers have been principally employed for marking plastic surfaces, such as IC packages. The laser beam from the laser is directed through a copper stencil to form the indicia on the plastic surface. However, due to the shrinkage of IC packages over the years, CO
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lasers, in many cases, are no longer suitable since high quality indicia with good visibility are required for this particular application. However, low cost, lower marking quality CO
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systems employing low cost X-Y galvanometer devices are still employed for applications not requiring high quality marking with high resolution indicia.
YAG lasers are extensively employed today for IC package marking as well as many other marking applications. YAG lasers have shorter wavelengths of operation permitting the marking of indicia on harder surfaces, such as ceramic material. The beam in the YAG marking systems is steered or scanned in one, two or three dimensions by means of a pair of displaceable mirrors mounted for rotation to displace a laser beam in orthogonal directions to form a two-dimensional scan of the beam on the surface to be marked, such as, for example, a X-Y galvanometer device or a X—X galvanometer device operated via a controller under computer control. Examples of two-dimensional scanners are disclosed in U.S. Pat. Nos. 5,225,923; 5,329,090; 5,719,372; and 5,724,412. Indicia is scribed onto the surface of an article to be marked with fine resolution and marking clarity on comparatively smaller surfaces, such as in the case of small IC packages. A specific example of a YAG laser system for this type of marking is the scanning Nd:YAG laser called the Laser Marker SL475E, manufactured by NEC Corporation of Japan. The marking parameters of this system are as follows: (1) Laser Oscillator: SL114K, (2) Laser Type: cw Nd:YAG laser, (3) Output: 50 W or above, (4) Number of Marked Characters: 40, (5) Marking Method: One stroke or vector, (6) Power at Marked Surface: 1 W, (7) Scanning Speed: 100 mm/sec., (8) Bite Size: 30 &mgr;m; and (9) Q-Switch Frequency: 3 kHz.
The disadvantage of these CO
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and YAG laser marking systems is the need in most instances for separate, expensive refrigerated chillers or water cooling units and corresponding cooler controller and power supply to maintain cooling of the cw operated laser diode arrays for pumping the YAG rod or cw operated CO
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marking lasers. The chillers are required in CO
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marking lasers due to the low efficiency in converting lamp pump light into a cw laser output.
Further, the modulation of these marking lasers is generally accomplished by means of modulating their optical output beams, such as with an acusto-optic modulator, to produce appropriate pulses for forming marking strokes or vectors that, together, form intelligent indicia on the article surface. As a result, as much as 20% to 30% of the power in the modulated output is lost due to this type of external modulation. The cw operation of these types of lasers is a waste of energy, requires continual maintenance of the lasers, and significantly reduces their overall lifetime utility. In the pulse mode, there is a large pulse-to-pulse variation in YAG marking lasers as they lack uniformity in the energy applied to the marking surface. Moreover, the external modulator, beside its high loss, does not last long in the field and needs to be replaced, and is an added and continuing cost to the laser marking system, along with its RF driver. Further, the YAG laser systems used for marking require first pulse suppression, i.e., when the laser is turned off the light has to be “bled off”. Also, these systems with their associated cooling units and large power supplies and large laser head takes up a consider amount of floor space in a manufacturing facility just for the purpose of product marking.
What is needed is a less expensive marking laser system that provides for direct marking “power-on-demand”, i.e., provides for marking output when indicia marking strokes are to be initiated and is completely extinguished when the indicia marking strokes are completed, while taking up minimal floor space.
It is an object of this invention to provide a fiber laser marking system pumped and modulated by a pump or seed diode pump source providing indicia marking power-on-demand.
SUMMARY OF THE INVENTION
According to one feature of this invention, a fiber gain medium marking system comprises a high power fiber gain medium consisting of a double clad fiber having a doped core surrounded by an inner pump cladding and providing an optical output for marking; a high power laser diode source for pumping the double clad fiber gain medium via an input into the inner pump cladding; and an optical scanner coupled to receive the marking output from the double clad fiber laser to scan the output over a surface of an article to be marked by sweeping the marking output in one, two or three dimensions to form strokes or vectors, the completion of which comprises indicia to be marked the article surface. The fiber gain medium marking system is characterized in that the laser diode source comprises a of plurality of discrete, separately mounted laser diode devices with their respective outputs individually coupled to a respective multimode fiber with the combined output ends of the multimode fibers fused and pulled into a single fiber output providing a multimode fiber output core. The use of separate devices eliminates the need for water cooling as used in the case of laser bars as such a source. This multimode fiber is spliced to a double clad fiber that has a cross-sectional dimension for its inner pump cladding that substantially matches the cross-sectional dimension of the pulled and fused multimo
Alvarez Ramon E.
MacCormack Stuart
Sanders Steven
Welch David F.
Carothers, Jr. W. Douglas
Le N.
Pham Hai C.
SDL Inc.
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