Façades for consumer products, such as consumer electronic products, must meet a variety of criteria in order to be commercially viable. Among those criteria are durability and visual appearance. Lightweight, strong, durable and visually appealing façades would be useful in consumer product applications, among others.
Broadly, the present disclosure relates to aluminum alloy bodies or products having improved surface appearance and/or abrasion resistance. One embodiment of producing such aluminum alloy bodies or products is illustrated in
After the preparing step (100), the aluminum alloy product is anodized (200) thereby producing an anodic oxide zone in the aluminum alloy product, wherein the anodic oxide zone is associated with the intended viewing surface of the aluminum alloy product. The anodic oxide zone generally has a thickness of from 0.07 mil to 4.5 mil (about 1.8 microns to about 114.3 microns).
After the anodizing step (200), the anodic oxide zone of the aluminum alloy product is treated (300) with an acid for a time sufficient such that the intended viewing surface of the anodized aluminum alloy product achieves one or both of the preselected surface appearance and the preselected abrasion resistance. After the treating step (300), the anodic oxide zone of the aluminum alloy product may be optionally colored (500). After the treating step (300) and any optional coloring step (500), the anodic oxide zone of the aluminum alloy product may be sealed (400).
The aluminum alloy may be any wrought aluminum alloy, or any casting aluminum alloy. Wrought aluminum alloys include the 1xxx, 2xxx, 3xxx, 4xxx, 5xxx, 6xxx, 7xxx, and 8xxx aluminum alloys, as defined by the Aluminum Association. Casting aluminum alloys include the 1xx.x, 2xx.x, 3xx.x, 4xx.x, 5xx.x, 7xx.x, and 8xx.x aluminum alloys.
The aluminum alloy may be a high strength aluminum alloy. As used herein, a “high strength aluminum alloy” is an aluminum alloy product having a longitudinal (L) tensile yield strength of at least 275 MPa. Examples of aluminum alloys suited to achieve such high strengths include the wrought 2xxx, 5xxx, 6xxx, and 7xxx aluminum alloys, as well as shape cast 3xx.x aluminum alloys. In one embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 300 MPa. In another embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 350 MPa. In yet another embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 400 MPa. In another embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 450 MPa. In yet another embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 500 MPa. In another embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 550 MPa. In yet another embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 600 MPa. In another embodiment, a high strength aluminum alloy product has a longitudinal (L) tensile yield strength of at least 625 MPa.
In one approach, a high strength aluminum alloy is a 2xxx aluminum alloy. In one embodiment, a 2xxx aluminum alloy comprises 0.5-6.0 wt. % Cu, and optionally up to 1.9 wt. % Mg, usually at least 0.2 wt. % Mg. In one embodiment, a 2xxx alloy is one of a 2x24, 2026, 2014, or 2x19 aluminum alloy.
In one approach, a high strength aluminum alloy is a 6xxx aluminum alloy. In one embodiment, the 6xxx aluminum alloy includes 0.1-2.0 wt. % Si and 0.1-3.0 wt. % Mg, optionally with up to 1.5 wt. % Cu. In one embodiment, a 6xxx aluminum alloy comprises 0.25 wt. %-1.30 wt. % Cu. In one embodiment, a 6xxx aluminum alloy comprises 0.25 wt. %-1.0 wt. % Zn. In one embodiment, a 6xxx alloy is one of a 6013, 6111 or 6061 aluminum alloy.
In one approach, a high strength aluminum alloy is a 7xxx aluminum alloy. In one embodiment, a 7xxx alloy comprises 4-12 wt. % Zn, 1-3 wt. % Mg, and 0-3 wt. % Cu. In one embodiment, a 7xxx alloy is one of a 7x75, 7x50, 7x55, or 7x85 aluminum alloy.
In one approach, the aluminum alloy is a wrought rolled product having a thickness of from 0.006 inch to 0.500 inch. In another approach, the aluminum alloy is a wrought extruded product. In another approach, the aluminum alloy is a cast plate product. In other embodiments, the aluminum alloy is a shape cast product, wherein the product achieves its final or near final product form after the aluminum alloy casting process. A shape cast product is in final form if it requires no machining after casting. A shape cast product is in near final form if it requires some machining after casting. By definition, shape cast products excludes wrought products, which generally require hot and/or cold work after casting to achieve their final product form. Shape cast products may be produced via any suitable casting process, such as die casting and permanent mold casting processes, among others.
In one embodiment, the shape cast products are “thin walled” shape cast products. In these embodiments, the shape cast products have a nominal wall thickness of not greater than about 1.0 millimeter. In one embodiment, a shape cast product has a nominal wall thickness of not greater than about 0.99 mm. In another embodiment, a shape cast product has a nominal wall thickness of not greater than about 0.95 mm. In other embodiments, the shape cast product has a nominal wall thickness of not greater than about 0.9 mm, or not greater than about 0.85 mm, or not greater than about 0.8 mm, or not greater than about 0.75 mm, or not greater than about 0.7 mm, or not greater than about 0.65 mm, or not greater than about 0.6 mm, or not greater than about 0.55 mm, or not greater than about 0.5 mm, or even less.
Referring now to
As used herein, “a preselected surface appearance of an intending viewing surface” means an appearance of an intended viewing surface that is preselected in advance of at least one of the anodizing step (200) and the treating step (300). The preselected surface appearance may be one or more of a preselected color tolerance (20) and a gloss tolerance (30), among others. Color tolerance (20) does not require application of a color to the aluminum alloy product. Color tolerance (20) may be of an uncolored anodized (200), treated (300) and sealed (400) aluminum alloy product.
As used herein, a “preselected color tolerance” means a tolerance relative to one or more of an “L* value”, an “a* value” and a “b* value” as per CIElab 1976, i.e., a preselected color tolerance is one or more of a preselected b*, a*, or L* tolerance as per CIElab 1976. A preselected b*, a*, or L* tolerance means the tolerance relative to a specified b*, a*, or L* value. For example, if a specified b* value is −0.5 and a tolerance of +/−0.1 is required, then the preselected b* tolerance is −0.4 to −0.6. Color tolerance may be measured using a Technidyne Corp. ColorTouch PC, or similar instrumentation.
In one embodiment, the preselected surface appearance comprises a preselected b* tolerance, where a preselected (target) b* value is selected, and the intended viewing surface of the final aluminum alloy product is within a specified tolerance of the preselected b* value. In one embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual b* value that is within the 1.0 unit of the target b* value. For example, if the preselected b* value is 5.3, and the b* tolerance is 1.0 unit, the anodized intended viewing surface of the final aluminum alloy product would achieve an actual b* value of from 4.3 to 6.3 (i.e., 5.3+/−1.0). In another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual b* value that is within the 0.5 unit of the target b* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual b* value that is within the 0.4 unit of the target b* value. In another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual b* value that is within the 0.3 unit of the target b* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual b* value that is within the 0.2 unit of the target b* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual b* value that is within the 0.1 unit of the target b* value.
In one embodiment, the preselected surface appearance comprises a preselected a* tolerance. In one embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 1.0 unit of the target a* value. For example, if the preselected a* value is −1.8, and the a* tolerance is 1.0 unit, the anodized intended viewing surface of the final aluminum alloy product would achieve an actual a* value of from −2.8 to −1.8 (i.e., −1.8+/−1.0). In another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 0.75 unit of the target a* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 0.5 unit of the target a* value. In another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 0.4 unit of the target a* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 0.3 unit of the target a* value. In another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 0.2 unit of the target a* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 0.1 unit of the target a* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual a* value that is within the 0.05 unit of the target a* value.
In one embodiment, the preselected surface appearance comprises a preselected L* tolerance. In one embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual L* value that is within the 2.0 units of the target L* value. For example, if the preselected L* value is 70, and the L* tolerance is 2.0 unit, the anodized intended viewing surface of the final aluminum alloy product would achieve an actual L* value of from 68 to 72 (i.e., 70+/−2.0). In another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual L* value that is within the 1.5 unit of the target L* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual L* value that is within the 1.0 unit of the target L* value. In another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual L* value that is within the 0.75 unit of the target L* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual L* value that is within the 0.5 unit of the target L* value. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes an actual L* value that is within the 0.25 unit of the target L* value.
In one approach, both b* and a* target values are preselected, and the intended viewing surface of the final aluminum alloy product realizes actual b* and a* values that are within specified tolerances, such as any of the tolerances provided above. In another approach, both L* and a* target values are preselected, and the intended viewing surface of the final aluminum alloy product realizes actual L* and a* values that are within specified tolerances, such as any of the tolerances provided above. In yet another approach, both L* and b* target values are preselected, and the intended viewing surface of the final aluminum alloy product realizes actual L* and b* values that are within specified tolerances, such as any of the tolerances provided above.
In another approach, all of b*, a* and L* are preselected, and the intended viewing surface of the final aluminum alloy product realizes actual b*, a* and L* values that are within specified tolerances, such as any of the tolerances provided above, and the tolerance is determined using Delta-E (1976), wherein:
Delta-E=((L*psv−L*mv)2+(a*psv−a*mv)2+(b*psv−b*mv)2)1/2
where:
The treating step (300) may result in decreasing the “yellowness” of an anodized aluminum alloy product. In this regard, the treating step (300) may result in the intended viewing surface of the final aluminum alloy product realizing a decrease in b* relative to a reference-version of the intended viewing surface of the aluminum alloy product in the anodized and sealed condition. The reference-version of the aluminum alloy product is made by excluding the treatment step (300) when processing the aluminum alloy product, i.e., the reference-version is anodized (200) and then sealed (400). Since the reference-version of the aluminum alloy product is made from the same aluminum alloy as the new (treated (300)) aluminum alloy product, both the new (treated (300)) product and the reference-version of the product will have the same product form and composition. The b* values of the reference-version and the new aluminum alloy products are measured after the sealing step (400), i.e., both are sealed under the same sealing conditions, after which their b* values are measured. In one embodiment, the intended viewing surface of the final aluminum alloy product realizes a decrease in b* of at least 0.10 unit relative to a reference-version of the intended viewing surface of the aluminum alloy product in the anodized and sealed condition. In another embodiment, the intended viewing surface of the final aluminum alloy product realizes a decrease in b* of at least 0.20 unit relative to a reference-version of the intended viewing surface of the aluminum alloy product in the anodized and sealed condition. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes a decrease in b* of at least 0.40 unit relative to a reference-version of the intended viewing surface of the aluminum alloy product in the anodized and sealed condition. In another embodiment, the intended viewing surface of the final aluminum alloy product realizes a decrease in b* of at least 0.60 unit relative to a reference-version of the intended viewing surface of the aluminum alloy product in the anodized and sealed condition. In yet another embodiment, the intended viewing surface of the final aluminum alloy product realizes a decrease in b* of at least 0.80 unit relative to a reference-version of the intended viewing surface of the aluminum alloy product in the anodized and sealed condition. In another embodiment, the intended viewing surface of the final aluminum alloy product realizes a decrease in b* of at least 1.00 unit relative to a reference-version of the intended viewing surface of the aluminum alloy product in the anodized and sealed condition.
The gloss tolerance (30) is measured on the intended viewing surface of the final aluminum alloy product and using 60° Specular Gloss using BYK-Gardner Haze-Gloss Meter and ASTM D523-08 Standard Test Method for Specular Gloss.
The intending viewing surface of the aluminum alloy product may be substantially free of visually apparent surface defects. “Substantially free of visually apparent surface defects” means that the intended viewing surfaces of the product are substantially free of surface defects as viewed by human eyesight, with 20/20 vision, when the aluminum alloy product is located at least 18 inches away from the eyes of the human viewing the aluminum alloy product. Visually apparent surface defects include, for instance, those cosmetic defects that can be viewed due to the alloy microstructure (e.g., the presence of randomly located particles at or near the intended viewing surface of the product), among others.
The preselected abrasion resistance (50) is the abrasion resistance of the intending viewing surface of the aluminum alloy product as determined via ASTM D4060-10 Standard Test Method for Abrasion Resistance of Organic Coatings by the Taber Abraser and using the test conditions (CS-17 wheel, 1000 g load, 70 RPM) as specified by MIL-A-8625F—Military Specification: Anodic Coatings for Aluminum and Aluminum Alloys (measure sample weight and reface wheel after 1000 cycles). In one embodiment, the preselected abrasion resistance is not greater than 100 mg weight loss per 1000 cycles. In another embodiment, the preselected abrasion resistance is not greater than 75 mg weight loss per 1000 cycles. In yet another embodiment, the preselected abrasion resistance is not greater than 50 mg weight loss per 1000 cycles. In another embodiment, the preselected abrasion resistance is not greater than 40 mg weight loss per 1000 cycles. In yet another embodiment, the preselected abrasion resistance is not greater than 35 mg weight loss per 1000 cycles. In another embodiment, the preselected abrasion resistance is not greater than 30 mg weight loss per 1000 cycles. In yet another embodiment, the preselected abrasion resistance is not greater than 25 mg weight loss per 1000 cycles. In another embodiment, the preselected abrasion resistance is not greater than 20 mg weight loss per 1000 cycles. In yet another embodiment, the preselected abrasion resistance is not greater than 16 mg weight loss per 1000 cycles.
Referring now to
Referring now to
Referring now to
In one embodiment, the treating step (300) comprises contacting the intended viewing surface of the anodized aluminum alloy product with nitric acid, such as via immersion in a nitric acid bath. The nitric acid may be a concentrated nitric acid (67% nitric acid by weight) or a diluted version thereof. For example, this concentrated nitric acid may be diluted 1:1 to achieve about a 33 wt. % nitric acid bath. In another example, this concentrated nitric acid may be diluted 5:1 to achieve about a 13.4 wt. % nitric acid bath. In yet another example, this concentrated nitric acid may be diluted 10:1 to achieve about a 6.7 wt. % nitric acid bath. In another example, this concentrated nitric acid may be diluted 100:1 to achieve about a 0.67 wt. % nitric acid bath. Thus, the nitric acid may be from 0.67% to 67% (wt.) of a liquid bath. Other concentrations may be employed.
The temperature of the acid solution (e.g., an acid spray or bath) should generally be from 40° to 110° F., and may depend on the type of alloy being treated. As shown by the below examples, if the acid solution temperature is too cold, preselected surface appearance properties may not be achieved and/or low throughput may be realized. If the temperature is too hot, the anodic oxide zone may be degraded (i.e., the preselected abrasive resistance may not be achieved) and/or the preselected surface appearance properties may not be achieved. In one embodiment, the acid solution has a temperature of from 60° F. to 100° F. In another embodiment, the acid solution has a temperature of from 60° to 95° F. In one embodiment, the acid solution has a temperature of from 70° to 90° F.
As noted above, and as shown by the below examples, when the determining step (10) is employed, the treatment step (300) should be sufficiently long to achieve the preselected surface appearance properties. However, the treatment step (300) should not be so long so as to degrade abrasion resistance (e.g., by unacceptably decreasing the anodic oxide zone thickness) and/or unnecessarily limit throughput. In this regard, the duration of the treating step (300) is generally from 1 minute to not greater than 60 minutes, and generally depends on the acid concentration and/or the treatment temperature and/or the alloy being treated. In one embodiment, the duration of the treating step (300) is at least 2 minutes. In another embodiment, the duration of the treating step (300) is at least 3 minutes. In one embodiment, the duration of the treating step (300) is not greater than 30 minutes. In another embodiment, the duration of the treating step (300) is not greater than 20 minutes.
As mentioned above, the treating step (300) may be accomplished to at least partially maintain the thickness of the anodic oxide zone. At least partially maintaining the thickness of the anodic oxide zone may facilitate achievement of any preselected abrasion resistance. More particularly, the anodizing step (200) will produce an anodic oxide zone having an average thickness, such as in the range of from about 0.07 mil to about 4.5 mil. This average anodic oxide zone thickness is sometimes referred to herein as the pre-treating (or pre-contacting) anodic oxide zone thickness. The treating step (300) may be accomplished so as to at least partially maintain this anodic oxide zone thickness. The thickness of the anodic oxide zone after the treating step (300) is sometimes referred to herein as the final anodic oxide zone thickness. In one embodiment, the final anodic oxide zone thickness is within 10% of the pre-treating anodic oxide zone thickness. For example, if the pre-treating anodic oxide zone thickness was 0.263 mil (about 6.68 microns), the final anodic oxide zone thickness would be no more than 10% less than 0.263 mil, i.e., the final anodic oxide zone thickness would be at least 0.2637 mil (at least about 6.01 microns). In another embodiment, the final anodic oxide zone thickness is within 7% of the pre-treating anodic oxide zone thickness. In yet another embodiment, the final anodic oxide zone thickness is within 5% of the pre-treating anodic oxide zone thickness. In another embodiment, the final anodic oxide zone thickness is within 3% of the pre-treating anodic oxide zone thickness. In yet another embodiment, the final anodic oxide zone thickness is within 1% of the pre-treating anodic oxide zone thickness.
In some embodiments, after the preparing step (100), the aluminum alloy product may comprise a plurality of particles, such as particles having an average size (D0.5) of from 0.100 micron to 30 micron, such as when the aluminum alloy is a high strength aluminum alloy. After the anodizing (200), at least some of the above-mentioned particles may be contained within the anodic oxide zone, i.e., some of the particles of the aluminum alloy product may be contained in the anodic oxide zone. Such particles may be detrimental, for example, to achievement of a predetermined surface appearance. Thus, the treating step (300) may include removing at least some of the particles contained within the anodic oxide zone via the acid (e.g., nitric acid). In one embodiment, the treating step (300) includes removing at least some of the particles contained within the anodic oxide zone via the acid. The treating step (300) may also include enlarging of the pores of the anodic oxide zone, which may also/alternatively facilitate achievement of a preselected surface appearance.
Referring now to
Referring now to
As noted above, the determining step (10) is optional. For example, the presently disclosed method may be useful in producing anodized aluminum alloy products simply by employing the preparing (100), anodizing (200), treating (300), and sealing (400) steps, optionally with the coloring (500) step. In this regard, the treating step (300) may be used to facilitate production of anodized aluminum alloy products having good surface appearance properties and abrasion resistance, and without the need to preselect any appearance and/or properties.
These and other aspects and advantages, and novel features of this new technology are set forth in part in the description that follows and will become apparent to those skilled in the art upon examination of the following description and figures, or may be learned by practicing one or more embodiments of the technology provided for by the present disclosure.
a-8b are graphs illustrating characteristics of alloy 7075 as a function of nitric acid dip (contact) time.
Aluminum alloy 7075 in a T6 temper is produced as a sheet. The sheet is then prepared for anodizing by cleaning, after which it is Type II anodized. The sheet is then dipped in a nitric acid bath (about 33% wt.) for various times and then sealed, after which various b* color measurements and abrasion resistances were measured. No coloring was applied between the nitric acid dip and the sealing. The results are shown in
Alloys 1090, 2024, 3103, 5657, and 6061 were processed similar to the processes of Example 1. Specifically, these alloys, in sheet form, were prepared for anodizing by cleaning, after which they were Type II anodized. The sheets were then dipped in a nitric acid bath (about 33% wt.) for about 8 minutes, and then sealed, after which each sheets' b* color value was measured. For comparison purposes, these same alloys, as well as alloy 7075, are also conventionally processed and without the nitric acid bath dip step of Example 1, i.e., the sheets were prepared for anodizing, Type II anodized, and then sealed, after which after which each sheets' b* color value was measured. The results are shown in Table 1, below.
All of the alloys, except alloy 5657, realize a less “yellow” appearance when using the new post-anodizing treatment step. This is shown by the b* values decreasing relative to the conventionally processed version of that alloy. Reflectance is also generally improved when using the new post-anodizing treatment step. The gloss and surface roughness of the samples processed according to the new process were comparable to the gloss and surface roughness of the samples processed according to the conventional process.
Alloy 7055 in sheet form is processed similar to the 7075 alloy of Example 1. Specifically, the 7055 sheet is prepared for anodizing by cleaning, after which it is Type II anodized. The sheet is then dipped in a nitric acid bath (about 33% wt.) for various times and then sealed, after which various b* values were measured. The results are shown in
Alloys 2024, 6013 and 7075 in sheet form were prepared for anodizing by alkaline cleaning for 2 minutes at 150° F., chemical polishing for 1 minute at 200° F., and a 1-minute nitric acid desmut (with intermediate water rinses), and then Type II anodized at 12 ASF, 70° F. for 10 minutes in a 20% by weight sulfuric acid electrolyte. The oxide thickness was then measured and ranged from about 0.23 to 0.30 mil (about 5.8 to 7.6 microns). A control sample (reference-version) of each of the alloys was then prepared by sealing the alloy in boiling water. The b* value of each control sample was then measured. Other portions of the alloys were then dipped in nitric acid baths for various times, at various bath temperatures, and at various nitric acid concentrations, and then sealed, after which b* color and oxide thickness were measured. Δb* was then calculated relative to the control sample, and oxide thickness loss (if any) was also calculated. The results are provided in Tables 2-4 below.
As shown above and in
As shown in
As shown in
Alloy 7075 in sheet form was prepared for anodizing by as per Example 4 and then Type II anodized per Example 4, but producing an anodic oxide zone thickness of approximately 0.40 to 0.45 mil (about 10.2 microns to about 11.4 microns). A control sample (reference-version) of the alloy was then prepared by sealing the alloy in boiling water. The b* value of the control sample was then measured. Other portions of the alloy were then dipped in various chemical solutions, at various bath temperatures, and at various concentrations, and then sealed, after which b* color, and oxide thickness were measured. Δb* was then calculated relative to the control sample, and oxide thickness was also calculated. No oxide loss resulted in any of these tests. The results are provided in Table 5, below.
“LFN” means ANODAL Deox LFN Liquid from Reliant Aluminum Products, LLC, 520 Townsend Ave., High Point, N.C. 2726. As shown above, all of the chemicals lower the b* values as compared to the control sample (reference-version), meaning that the alloys realize a less “yellow” appearance when using the new post-anodizing treatment dip step. These results indicate that any of nitric acid, phosphoric acid, acetic acid, sulfuric acid, and combinations thereof may be used as a post-anodizing solution to reduce “yellowness” of an anodized aluminum alloy.
While various embodiments of the new technology described herein have been described in detail, it is apparent that modifications and adaptations of those embodiments will occur to those skilled in the art. However, it is to be expressly understood that such modifications and adaptations are within the spirit and scope of the presently disclosed technology.
This patent application claims priority to U.S. Provisional Patent Application No. 61/704,958, entitled “ANODIZED HIGH STRENGTH ALUMINUM ALLOY PRODUCTS HAVING PRESELECTED SURFACE APPEARANCE AND ABRASION RESISTANCE, AND METHODS OF MAKING THE SAME”, filed Sep. 24, 2012, and which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61704958 | Sep 2012 | US |