Laser-made microperforations in films

Abstract

A laser system and method is used to micro-drill a web producing holes of approximately 85 m or less. The laser system comprises a laser beam having a wavelength in the range of approximately 2 to 6 microns and the focal point of the laser beam being steered onto a surface of the moving web wherein the web is moving.. The web is a film such as a flexible film or commercial packaging film. The laser beam wavelength and constant laser energy can be used to laser micro-drill the flexible film.

Claims

1. A method of micro-drilling a moving web comprising: providing a laser system for production of a laser beam having a wavelength in the range of approximately 2 to 6 microns; steering a focal point of the laser beam on a surface of the moving web concurrently with moving the web and producing one or more holes in the moving web wherein the moving web has a thickness of approximately 20 to 150 m, whereby the laser is pulsed at a duration of approximately 1 sec to 750 sec producing holes having a diameter in the range of approximately 85 m or less; and moving the web while producing the holes.

2. The method of claim 1 wherein the holes have a repeating circular configuration.

3. The method of claim 1 wherein the laser beam has an approximate wavelength of 5 microns.

4. The method of claim 1 wherein the hole or holes have a diameter in the range of approximately 25 m to 95 m.

5. The method of claim 1 wherein the hole or holes have a diameter in the range of approximately 35 m to 85 m.

6. The method of claim 1 wherein the flexible material comprises a polymer film.

7. A method of micro-drilling a film for use as a modified atmosphere packaging by using a laser system, the method comprising directing a focal point of a laser beam of the laser system onto a surface of the film to form holes in the film, the holes having a diameter less than approximately 85 m while moving the film through the laser system wherein the moving web has a thickness of approximately 20 to 150 m and whereby the laser is pulsed at a duration of approximately 1 sec to 750 sec.

8. The method of claim 7 wherein the laser beam has a wavelength in the range of approximately 2 to 6 microns.

9. The method of claim 7 wherein the laser beam has a wavelength of approximately 5 microns.

10. The method of claim 7 wherein the diameter of the holes is in the range of approximately 25 m to 95 m.

11. The method of claim 8 wherein the holes have a diameter in the range of approximately 35 m to 85 m.

12. A method of micro-drilling a flexible film with a laser system, the method comprising directing a focal point of a laser beam produced by an approximately 2 to 6 micron wavelength laser onto a surface of the film to form holes in the film, the holes having a diameter approximately less than 85 m while moving the film through the laser system wherein the moving web has a thickness of approximately 20 to 150 m, whereby the laser is pulsed at a duration of approximately 1 sec to 750 sec and wherein the flexible material is then incorporated into pet food bags.

13. The method of claim 12 wherein the diameter of the holes is in the range of approximately 25 m to 95 m.

14. The method of claim 12 wherein the holes have a diameter in the range of approximately 35 m to 85 m.

15. The method of claim 12 where in the laser has an approximate wavelength of 5 microns.

16. A method of laser perforating a commercial packaging film with a mid-infrared wavelength laser beam at a constant laser energy while moving the commercial packaging film through a laser system at a commercial production speed to micro-drill holes in the film having a diameter less than approximately 85 m.

17. The method of claim 16 wherein the wavelength of the laser beam is in the approximate range of 4 to 10 microns.

18. The method of claim 17 wherein the wavelength of the laser beam is approximately 5 microns.

19. The method of claim 16 wherein the diameter of at least a portion of the holes is in the range of approximately 25 m to approximately 95 m.

20. The method of claim 16 wherein the diameter of at least a portion of the holes is in the range of approximately 35 m to approximately 85 m.

21. The method of claim 16 and steering the laser beam with respect to the commercial packaging film moving through the laser system with a single axis galvanometer.

22. A method of laser perforating a moving web comprising: providing a laser system for production of a laser beam having a wavelength in the range of approximately 2 microns to 6 microns; steering a focal point of the laser beam on a surface of the moving web concurrently with moving the web and producing one or more holes in the moving web wherein the hole or holes have a diameter in the range of approximately 85 m or less; and moving the web at least approximately 200 feet per minute while producing the one or more holes.

23. The method of claim 22 wherein the moving web is a flexible film.

24. The method of claim 22 wherein the hole or holes have a diameter in the range of approximately 35 m to 85 m.

25. A method of perforating a film for use as a modified atmosphere packaging by using a laser system, the method comprising directing a focal point of a laser beam of the laser system onto a surface of the film to form one or more holes in the film, the one or more holes having a diameter less than approximately 85 m while moving the film through the laser system at a speed approximately 200 feet per minute or greater.

26. The method of claim 25 wherein the laser beam has a wavelength in the range of approximately 5 m to 10 m.

Description

DESCRIPTION OF THE DRAWINGS

[0020] FIG. 1 is a diagram of a laser system and web according to the present specification.

DETAILED DESCRIPTION

[0021] If everything is stationary, generally speaking the diameter of the hole created is directly related to the diameter of the focused spot of the laser and how well the material reacts to the wavelength of the laser. The simple lens equation to calculate the diameter of the focused spot

[00001]${\mathrm{FS}}_D=\frac{4.Math.\left(\mathrm{Beam}.Math..Math.\mathrm{Quality}\right)O_{\mathrm{FL}}}{{\mathrm{RB}}_D}$

[0022] Where FS.sub.D is the diameter of the focused spot;

[0023] 4 (Beam Quality) is the geometry of the Gaussian representation in 4 standard deviations of the laser beam (Beam quality is sometimes referred to as M.sup.2);

[0024] is the wavelength of the laser beam;

[0025] O.sub.FL is the focal length of optic;

[0026] is Pi; and

[0027] RB.sub.D is the diameter of the raw or source laser beam.

[0028] From this equation, as the wavelength gets longer, the diameter of the focused spot gets larger and as the wavelength gets shorter, the diameter of the focused spot gets smaller. Many prior art applications utilize a CO.sub.2 laser for packaging industry applications producing a laser beam of 9.36, 10.6 or 10.2 m wavelength. Using the shortest practical lens with a CO.sub.2 laser generates a focused spot size diameter of about 75 microns and which will produce the smallest hole of about 85 microns. To make larger holes a longer focal length lens can be used or commonly the beam is defocused. There is a limit on how long of a focal length can be practical and how far out of focus is reasonable to defocus the spot size.

[0029] Prior to this disclosure, the industrially available lasers were the CO.sub.2 family (10.6, 10.2. and 9.36 m) as discussed previously, the 1 micron laser family (1030-1090 m), the 1 micron frequency doubled laser family (0.515-0.545 m) and the 1 micron frequency tripled laser family (0.343-0.363 m). The 1 m laser family will produce about a 10 times smaller focused spot than the CO.sub.2 laser family. The 1 micron frequency doubled family is about 20 times smaller and the 1 micron frequency tripled is about 30 times smaller. The problem is that the normal 1 micron, frequency double or tripled wavelength does not absorb/couple well with the packaging materials.

[0030] There are lasers that are in the pico and femto second family of pulse width that the material interaction with these lasers can be acceptable to the process of making a hole, but the size of the focused spot is much too small to make a sized hole between 35 and 85 microns. If the beam was defocused, to the point of achieving a diameter within this range, the interaction with the material no longer couples well. Thus to make a hole with pico and femto second lasers, the laser beam must profile a hole to get the desired hole diameter. Profiling a hole to produce the hole results in a removal rate too slow for a method to produce a hole at a cost effective rate for the packaging industry where throughput of packaging material is critical to packaging cost.

[0031] The CO laser (carbon monoxide) has a laser wavelength approximately 5 microns or about half of the CO.sub.2 (carbon dioxide) laser wavelength. Using the CO laser holes between 35 and 85 microns are produced without the need for profiling or contouring, instead holes within the 35 and 85 micron range are produced on a repeatable basis by using the diameter of the focused spot.

[0032] The laser system of this disclosure is configured to laser score, contour score, and/or perforate various films for consumer and industrial applications. The laser system and method described herein produces a hole in the film by pointing, tracking, and shooting a target area with the laser beam. The method eliminates the need for contouring the holes for formation of the holes. Instead the holes are formed by drilling the holes using a point and shoot method that is faster than prior art contouring methods. Laser drilling is a phrase that has been used to describe prior art methods of creating holes. For purposes of this patent application the phrase micro-laser drilling is used to describe a process in which the holes being created are essentially the same diameter as the focused spot creating the holes. This phrase is introduced herein to distinguish over the prior art reference to drilling holes. Holes created by prior art methods (sometimes referred to as contour drilling) are generally much larger in diameter than the diameter of the focused beam creating the hole. Another aspect of the process of this disclosure is that a constant energy laser beam is used to micro-drill the holes. Using constant energy helps in repeatability in creating the substantially same size hole while the web is moving.

[0033] The moving film or web creates another issue for producing a substantially round hole. The term round hole is a term of art and is sometimes loosely defined, but as used in this disclosure, round hole refers to a substantially circumferential shape and in all instances it is not the shape of a slot. In a typical situation, the amount of time the laser beam is on will create a slot instead of a round hole when the film or web is moving. To produce a substantially round hole, the laser beam is synchronized with the moving web or film such that the laser spot is stationary in relation to the target area since the laser spot moves with the speed of the web or film thereby producing a substantially round hole. The synchronization of speed may be accomplished by a single axis galvanometer scanhead system which is described in U.S. Pat. No. 6,177,648 which is hereby incorporated in its entirety.

[0034] Holes smaller than 85 microns can be created with a CO.sub.2 laser, but the process of making such holes with a CO.sub.2 laser are not very capable or repeatable processes. An analogy can be made to the use of a conventional drill bit. With a drill bit it is easy to make diameter holes. A drill bit is designed to that; however a drill bit if carefully used can create a hole. You need to stop drilling at the perfect depth that the tapered point breaks through and leaves a hole. This is not a robust or repeatable process, but it can be done. If you want a hole, it is best to use a drill bit. Similarly a CO.sub.2 laser can make holes smaller than 85 microns, but it is not very repeatable for similar reasons.

[0035] An M.sup.2 of 1 is the theoretical perfect beam quality and higher numbers indicate a decreasing beam quality. Using the spot size equation, best beam quality gives the smallest available spot size for the particular wavelength. The laser system of this disclosure incorporates a mid-infrared wavelength laser and scanning technology such as described in U.S. Pat. No. 6,177,648 supported over a moving web. The use of the term galvo or galvanometer refers to a scanner which in its simple form includes a mirror attached to the end of a shaft which in turn is moved by a motor which when controlled steers a laser beam by way of the mirror to a selected position whether it be to a work piece or to another galvo. The use of the terms galvo, galvanometer or scanner may be used interchangeably herein. Although the embodiments described herein refer to a 5 micron wavelength laser, additional and alternative laser wavelengths are also contemplated for scoring and perforating materials according to this disclosure. For example, a fiber laser having a wave length of approximately 2 to 3 microns may also be sufficient to produce the perforations in a moving web as described herein . A possibly suitable fiber laser is made by IPG Photonics of Oxford, Mass.

[0036] Referring to the drawings, a laser system 10 is configured for moving a focused laser beam spot at a point where it impinges on the advancing web or film (product) in the same direction as the product is moving. The laser system 10 comprises a laser source 12 which generates a laser beam 14 that is focused by a lens 16 and reflected onto an advancing web 18. The web 18 is carried by rollers 22 or a similar advancement mechanism known in the art, moving in the direction indicated by arrow 23. The laser beam 14 is steered such that the focal point of the laser beam 14 moves linearly on the web 18 and produces holes 19 in the web 18 at the spot where the focal point (also referred to herein as the focused spot or laser spot) impinges on the web 18. The laser beam may be steered by a galvanometer scanhead (also referred to as a galvo) 20. The speed of movement of the focal point of the laser beam 14 can be selected based on the laser power, the speed of advancement of the web 18, and the selected size and/or shape of the laser processed holes to be produced. The focal point of the laser beam or laser spot size is selected to produce holes 19 of a selected diameter and the focal point or laser spot is directed onto a surface of the web 18.

[0037] The term hole as used throughout this disclosure refers to scoring or perforating the material, regardless of the depth of the score or perforation, including through-holes. The score or perforation diameter size is modified by using different collimator lens options or different focusing lenses. The laser beam 14 is focused to produce the laser spot that is directed to the web such that when the laser spot impinges on the web, the hole of the selected diameter is produced.

[0038] The laser system 10 is configured to laser perforate the web 18. What is meant by the term web as used herein is a material or product for laser processing, examples of which include but are not limited to commercial packaging ready for its end-use such as those packaging materials comprising flexible films such as polymer films or constructions of polymer films. For example, the film may be a polyester, polypropylene, polyethylene, PTFE or polymer coextruded film or combinations of thereof and other polymers that typically constitute multi-layered films. The material or product may be provided on a roll for continuous processing or otherwise provided in sheets.

[0039] The laser system 10 utilizes a laser source 12 operating at a wavelength in the mid-infrared range in combination with web speed sufficient for commercial processing speeds that can produce micro-perforations in the web along a selected pattern. The laser source 12 may be a CO laser having a wavelength in approximately the 5 micron range. The laser source 12 may alternatively be a frequency doubled CO.sub.2 laser which can generate a 5 micron laser beam. More generally, the wavelength may be in the range of approximately 4-6 micron. As described herein, the laser system 10 and a method of micro-perforating a packaging material utilizes an approximately 5 micron wavelength laser 12.

[0040] The commercial processing speed (e.g., web speed) at which the web 18 advances through the laser system 10 as described herein is preferably at least about 200 feet per minute (fpm) or more for micro-drilling the material with the mid-infrared laser wavelength for producing holes in the web 18 that have a diameter in the range of about 25 m or less to about 95 m, and more specifically in the range of 35 m to 85 m as selected based on the end use of the material or the selected application. However, slower processing speeds are equally contemplated.

[0041] The laser system 10 may be configured with a galvo that allows for micro-perforating the material with the mid-infrared laser wavelength for producing holes in the web 18 that have a diameter in the range of about 25 m to about 95 m, or more specifically in the range of about 35 m to 85 m at a web speed of up to about 2,500 fpm. Depending on the material thickness, laser power, and hole density, the web speed can range up to 2500 fpm for micro-perforating the holes 19. It should be understood that perforations are typically approximately the same size for any one application and that the ranges being given are sizes that can be selected and produced under this disclosure as needed for discrete applications.

[0042] While there are numerous applications for packaging construction that can benefit from laser perforated holes 19 as small as approximately 35 m or even smaller, such as 25 m or less in diameter, two examples are described further below to aid in the understanding of this disclosure.

EXAMPLE I

[0043] Fresh cut lettuce is generally sold in Modified Atmosphere Packaging (MAP). MAP is packaging comprised of flexible film that is effective in maintaining quality of the goods packaged therein through its effect on modification of the gas composition in the package. The packaging is configured with one or more holes to allow for gas transfer through the packaging as produce respires (O.sub.2 uptake and CO.sub.2 evolution of the packaged produce) to extend freshness of the packaged produce. Perforations in the film that are in the range of approximately 35 m to 85 m, and more specifically are closer to approximately 35 m in diameter achieve increased shelf life of the packaged produce. The laser system 10 using an approximately 5 micron wavelength laser at a web speed of approximately 200 fpm produced one or more perforations approximately 35 m in size in the film. The laser micro-perforation method described herein lowers the cost associated with producing a modified atmosphere package for lettuce.

EXAMPLE 2

[0044] The laser system 10 and method of perforating the web 18 described herein produced one or more holes having a diameter less than approximately 85 m, for example as small as approximately 35 m in diameter for use in packaging such as pet food packaging. The method of laser micro-perforation enables rapid filling, sealing, and stacking of pet food package.

[0045] Holes approximately 35 m in diameter are large enough to allow for air evacuation when stacking filled and sealed bags, but small enough to prevent mite infestation at a consumer/user location.

[0046] The laser system 10 and method described herein can be used with a variety of materials and films as well as readily available packaging films while laser perforating the material with holes in approximately the 35 m diameter range at production speeds in excess of about 200 feet per minute.

[0047] Although the present disclosure has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the disclosure.