The present invention relates to a process for manufacturing anodized, colored aluminum.
Anodized aluminum is used in a variety of applications including building materials, household appliances, automotive trim, foil applications, farm equipment, furniture, sporting goods, and containers. Anodized aluminum products are desirable because they exhibit many beneficial functional characteristics such as: resistance to corrosion, chemical staining, and fading; electrical insulation; and exceptional structural rigidity.
Currently, most anodized aluminum is manufactured in two-sided sheet or coil form, where (1) both sides of the sheet or coil are anodized with a sulfuric acid anodizing process or (2) both sides of the sheet or coil are anodized with a phosphoric acid anodizing process. Sulfuric acid anodized aluminum is readily colored, and therefore is suitable for applications requiring a decorative finish. However, conventional sulfuric acid anodized aluminum is incompatible with most commercially available adhesives. Accordingly, it is difficult to adhere sheets of decoratively finished sulfuric acid anodized aluminum to other materials.
In contrast, phosphoric acid anodized aluminum satisfactorily bonds with commercially available adhesives, and thus is a good candidate for applications where anodized aluminum sheets must be adhered to other materials. However, phosphoric acid anodized aluminum is difficult to color. Accordingly, although the phosphoric acid anodized acid sheets are readily bonded with other materials, the color of the sheets is limited to a dull-grayish finish.
A drawback of conventional anodizing processes is that both sides of manufactured sheets and coils of anodized aluminum either exhibit the desirable decorative function of sulfuric anodized aluminum or exhibit the desirable enhanced adhesion characteristics of phosphoric acid anodized aluminum. As a result, in many applications of anodized aluminum, one must weigh the trade-off between the decorative function and the adhesion characteristics.
The aforementioned problems are overcome in the present invention that provides an etching process in which one side of an anodized aluminum web or sheet is etched to form an improved adhesion surface and the other side of the web or sheet retains its pre-etching finish.
In a preferred embodiment, the present invention generally includes: providing a web or sheet of aluminum, anodized on both sides, and etching one side of the web. Preferably, etching creates an improved adhesion surface on the etched side, referred to as the “bond side,” but does not affect the other side of the web or sheet. Thus, the other side of the web or sheet retains its pre-etch finish, which is preferably decorative. The un-etched side is typically referred to as the “show side” because it is usually viewable or shown.
Etching creates many minute protrusions and superficial pockets or pores on or in the surface of the anodized aluminum. In effect, the surface area of this anodized aluminum significantly increases. Thus, adhesive applied over this roughened and increased surface readily bonds mechanically to the structures. Because of this mechanical bonding, the resultant etched surface of the anodized aluminum exhibits superior adhesion and bonding strength.
Etching is carried out by applying an etching composition to the bond side of the sheet or web. A preferred etching composition is a solution of sodium hydroxide, however, other compositions may be used, for example any alkaline or acidic media that is capable of dissolving aluminum oxide. Optionally, the composition is prevented from contacting the show side by techniques including: blowing air against the show side; administering a liquid over the show side; masking the show side with a film or sheet; and/or protecting the show side with a shield adjacent the show side.
The etching composition, preferably in a solution form, may be applied to the future bond side of the web or sheet in a variety of manners, for example: by cascading the etching solution over the bond side; by misting the etching solution over the bond side; by spraying the etching solution onto the bond side; by dipping the sheet or web into the etching solution where the show side is covered with a film and the bond side is exposed; and by rolling or brushing the etching solution onto the bond side.
Optionally, heat or temperature regulated air flow may be applied on the show side to affect the etching process on the bond side of the sheet.
The present inventive process, related apparatus and resultant product provide a significant benefit in that it is now possible create anodized aluminum sheets and webs that include both a decorative side and a bonding side with superior bonding capabilities.
These and other objects, advantages and features of the invention will be more readily understood and appreciated by reference to the detailed description of the preferred embodiments and the drawings.
In the present invention, the etching composition may be a solution of water or other suitable liquid and an alkaline, acidic or other caustic material, capable of dissolving aluminum oxide referred to as an “etching solution.” A preferred etching solution is a solution of sodium hydroxide of about 0.1 to about 0.5 molar. Optionally, sodium hydroxide solutions of about 0.5 to about 1.5 molar, and 1.0 to about 4 molar may also be used. Alternatively, the etching solution may be a solution of phosphoric acid in concentrations of preferably about 0.1 to about 5.1 molar, more preferably about 0.5 to about 3.0 molar and most preferably about 0.75 to about 1.5 molar. As will be appreciated, solutions of sulfuric acid may also be used, however, the temperature and duration of time required to sufficiently dissolve an aluminum oxide layer must be significantly increased relative to the temperature and duration required with sodium hydroxide solutions and phosphoric acid solutions.
With reference to
The structure of
A preferred embodiment of an etching system 10 for applying etching compositions to a web is depicted in
Unless otherwise specified, as used herein, “web” means a length of aluminum including top and bottom surfaces anodized before treatment in the tank 50. The anodizing of raw aluminum may occur at the anodizing station 30 (which is shown in a condensed form). The surfaces may be anodized using a conventional anodizing process such as sulfuric acid anodizing or phosphoric acid anodizing. In the preferred embodiment, the web is sulfuric acid anodized with a sulfuric acid concentration preferably of about 50 to 100 grams per liter, and more preferably about 150 to 400 grams per liter. As will be appreciated, sheets of anodized aluminum and individual pieces of aluminum structures may be etched in a manner similar to that described herein in connection with the web.
Preferably, before introduction to the tank 50, the web 100 is colored or sealed according to commercially acceptable coloring and sealing practices. The coloring and/or sealing may also occur at station 30 which, for purposes of disclosure, may comprise one or more individual stations, for example an anodizing station, a coloring station and/or a sealing station. If colored, both surfaces of the web is colored. Optionally, the web 100 also may be brightened, polished, cleaned or desmutted using commercially acceptable methods before introduction into the tank 50.
The etching system of
In the preferred embodiment, the etching solution 20 is a solution of sodium hydroxide having a concentration of about 0.05 to about 5 molar, preferably 0.1 to about 2 molar and more preferably about 0.1 to about 0.5 molar. Optionally, other caustic etching compositions at other concentrations may also be used as desired.
The etching system 10 may also include a diverter 80 to prevent etching solution 20 from contacting the upper surface 101 of the web. In one embodiment, the diverter 80 is a blower that blows a gas, for example, air, through ports 82 onto the upper side 101 and prevents etching solution 20 from etching that upper side. Optionally, the blower 80 may be replaced with a sprayer or mister that sprays or mists a liquid, such as water, through ports 82 onto the upper side 101 and prevents etching solution 20 from etching that upper side. Further, the blower or sprayer or mister may include a temperature-regulating element to heat or cool the gas or liquid dispelled therefrom. Temperature regulation may be used to further control the etching process on the underside 102 of the web. For example, the air may be heated to speed-up the caustic action of the etching composition on the underside 102 of the web. The exact amount of heat or cooling applied to the web may be monitored and controlled to etch the web as desired.
In another embodiment, the upper side 101 may be masked with a plastic or other synthetic film (not shown). Alternatively, a protective shield (not shown) constructed of a material such as plastic or non-corrosive metal, may be disposed adjacent the upper side 101 of the web 100. Of course, sometimes the film may not entirely contact or the shield may not fully cover the upper side 101. Thus, portions of the upper side 101 may become contaminated with etching solution. These portions optionally may be trimmed from the web 100 as desired. As will be appreciated, trimming may be utilized in any embodiment disclosed herein.
The operation of the etching apparatus of
Preferably, the lower surface 102 of the anodized aluminum web 100 is exposed to the etching solution for about 1 to about 240 seconds, more preferably about 10 to about 100 seconds and most preferably about 20 to about 60 seconds. The temperature of the etching solution is preferably 50° F. to about 300° F., more preferably 10° F. 0 to about 212° F., and most preferably about 70° F. to about 160° F. Of course, the temperature and exposure time may vary according to the concentration of the caustic composition and the desired degree of etching.
Optionally, the etching solution 20 may be prevented from contacting the upper surface 101 during application by blowing, spraying, misting or applying a gas or liquid with diverter 80 over upper surface 101, applying a film to the upper surface 101, or using a protective shield over upper surface 101 as explained above.
Notably, after traversing the etching system 10, the upper surface 101 of the web, also referred to as the “show side,” is un-etched, however, the lower surface 102 of the web, also referred to as the “sticky side” or “bond side” is etched.
The tank 250 optionally includes an etching composition diverter 280, which is similar in structure and operation to the preferred embodiment, and therefore will not be explained in detail here. Alternatively, the diverter 280 may be substituted with a shield member (not shown) disposed over the upper surface 201 of the web, or the upper surface 201 may be coated or covered with a plastic or other synthetic film (not shown) to prevent the etching solution from contacting the upper surface 201 as described in the preferred embodiment above.
The etching system 210 may further include a drain 252, pump 254 and back flow line 256 to circulate etching solution 220 in the form of a liquid for re-use. An anodizing, coloring and/or sealing station 230 may be upstream of the tank 250 to perform the anodizing, coloring and/or sealing of a raw aluminum web before the web advances to the tank 250.
The operation of the first alternative embodiment of the etching system 210 in
In the embodiment depicted in
In operation, before the anodized web 300 is guided through the etching solution 320 in the tank 350, the upper side 301 is masked with a polyfilm such as a conventional plastic or synthetic film, coating or covering. The etching solution may be any of the etching compositions described in connection with the preferred embodiment. When the web 300 is guided through the etching solution 320, only the under side 302 comes into contact with the etching solution 320 to become etched.
In the embodiment depicted in
A sulfuric acid anodized web was selectively etched on one side with 0.1 molar sodium hydroxide for 30-60 seconds at 140° F. After removing excess sodium hydroxide from the etched side with nitric acid, the adhesion strength of the etched side preparation was compared with alternate preparations of (1) sulfuric acid anodized aluminum and (2) sulfuric acid anodized aluminum coated with a conventional chromic acid conversion treatment. Conventional ASTM D1876 testing methods were observed in carrying out the comparative test. For this test, a 1 ml layer of 3MDP430 epoxy adhesive, available from 3M Corporation of St. Paul, Minn., was applied to a piece of sample material of each of the alternate preparations. A second piece of like material was then secured to each sample piece. For example, the sulfuric acid anodized piece was mated to a like sulfuric acid anodized piece, and so on. But for the selectively etched pieces prepared according to the process of the present invention, the sample and like piece were mated so the etched surfaces of the samples faced each other.
Next, the adhesive was cured at 235° F. for one hour. Each sample of material was cut into 1 inch wide t-peel specimens and subjected to a tensile pull tester operating with a crosshead speed of 10 inches per minute. The comparative results of the tensile pull test are presented in Table I below.
As Table I demonstrates, the anodized aluminum treated with sodium hydroxide etching solution of the preferred embodiment exhibits superior failure thresholds when compared to sulfuric acid anodized aluminum and chromate conversion aluminum specimens. Specifically, the single-sided sodium hydroxide etched samples exhibited cohesive failure at around 30-60 lb./in., meaning the epoxy adhesive itself failed and was torn apart, leaving pieces of epoxy on both strips of pulled-apart sample. In contrast, the dual-sided sulfuric acid anodized sample and dual-sided chromic conversion sample exhibited adhesive failure at less than 3 lbs./in. and less than 6 lbs./in., respectively, meaning the epoxy adhesive did not fail, but was pulled-off from the surface of at least one surface of adjoining sample strips.
The above descriptions are those of the preferred embodiments of the invention. Various alterations and changes can be made without departing from the spirit and broader aspects of the invention as defined in the appended claims, which are to be interpreted in accordance with the principles of patent law including the doctrine of equivalents. Any references to claim elements in the singular, for example, using the articles “a,” “an,” “the,” or “said,” is not to be construed as limiting the element to the singular.
This is a continuation of U.S. application Ser. No. 09/899,591 filed Jul. 5, 2001 (now U.S. Pat. No. ______), which claims the benefit of U.S. Provisional Application No. 60/263,408, filed Jan. 23, 2001.
Number | Date | Country | |
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60263408 | Jan 2001 | US |
Number | Date | Country | |
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Parent | 09899591 | Jul 2001 | US |
Child | 11294016 | Dec 2005 | US |