AU767358B2 - An anticorrosion treatment - Google Patents
An anticorrosion treatment Download PDFInfo
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- AU767358B2 AU767358B2 AU41242/99A AU4124299A AU767358B2 AU 767358 B2 AU767358 B2 AU 767358B2 AU 41242/99 A AU41242/99 A AU 41242/99A AU 4124299 A AU4124299 A AU 4124299A AU 767358 B2 AU767358 B2 AU 767358B2
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- solution
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- molybdenum
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Description
WO 99/61681 PCT/AU99/00419 AN ANTICORROSION TREATMENT The present invention relates to an anticorrosion treatment of aluminium/zinc alloy surfaces.
In particular, although by no means exclusively, the present invention relates to an anticorrosion treatment of steel -strip having a coating of an Al/Zn alloy.
Zinc, aluminium and/or combinations of aluminium and zinc are widely used as surface coatings, particularly but not exclusively for steel for protection against corrosion. In practice, however, the zinc or Al/Zn coatings are susceptible to white corrosion (white rust) or black corrosion (black rust) respectively when exposed to the atmosphere due to reactions with moisture. Such corrosion is detrimental to the surface appearance and generally makes coated steel substrates unacceptable commercially despite the fact that the overall'service life of the coated steel may remain the same. Further the formation of corrosion products generally interferes with finishing operations. The ability to resist such corrosion is referred to herein as wet stack performance.
In order to inhibit the formation of corrosion on coated surfaces it is generally accepted that the treatment of a surface with a chromate imparts anticorrosive properties and this type of treatment is generally referred to as chromate passivation. However, chromate is highly toxic to exposed workers and, due to its high toxicity, disposal of chromium residues is difficult. Further, in various markets yellow discolouration of treated coated surfaces caused by the chromate is considered to be an unacceptable product attribute.
WO 99/61681 PCT/AU99/00419 2 In order to overcome the problems associated with chromate passivation, phosphate coatings have been used.
However the anticorrosion properties of phosphate have been found to be far inferior to the above-mentioned chromate treatment.
US patent 4,385,940 assigned to Kobe Steel, Limited discloses an anticorrosive treatment for preventing white rust on galvanized steel which includes the steps of applying to the surface of a galvanized steel sheet an acidic solution containing molybdic acid or a molybdate in a concentration of 10-200 g/l (calculated as molybdenum) and adjusted to a pH of 1 to 6 by addition of an organic or inorganic acid. However, whilst the anticorrosive treatment described in the US patent works well for galvanised steel, it has been found that the corrosion resistance of Al/Zn alloy surfaces treated with the above solution is inferior to the chromate treated substrates under certain conditions and the treated surfaces suffer from an undesirable degree of discolouration. Moreover, molybdate treated surfaces of such material have been observed to change from a pale yellow/blue to a strong green colour when stored for periods of time in excess of 24 hours.
International application PCT/US97/00012 (W097/27001) in the name of Henkel Corporation discloses an anti-corrosive treatment for aluminium/zinc alloy surfaces which is based on the use of a solution that includes phosphate anions and molybdenum anions and/or compounds in which the molybdenum has an oxidation state less than +6.
It is an object of the present invention to provide an alternative anticorrosion treatment for Al/Zn alloy surfaces.
According to the present invention there is 22/09 2003 09:29 FAX 61 3 92438333 0 provided an ant alloy surface (i) GRIFFITH HACK IPAUSTRALIA R006 3 ticorrosion treatment of an aluminium/zinc which includes the steps of: forming on the surface a coatizg of a chromium-free solution which contains 5-40 grams of molybdenum per litre of the solution, with the molybdenum having an oxidation state of +6 2-19% bylvolume of a phosphoric acid, and a surface etchant; and (ii) drying the coating to form a dried coating having a loading of molybdenum of at least mg/m 2 of the dried coating aind of phosphorus of at least 15 mg/mi of the dried coating.
The amount of 2-19 volume% of the phosphoric acid equates to 9.1 to 86.9 grams phosphorus per litre of the solution.
The applicant has found in laboratory and outdoors testing that coatings having the above molybdenum and phosphorous loadings exhibit excellent levels of corrosion resistance and lower levels of discolouration than prior art coatings.
Whilst not wishing to be bound by the following conmments in this paragraph, the applicant believes that the excellent performance of coatings having the above loadings of molybdenum and phosphorus is due to the above-described anticorrosion treatment initially forming a layer of zinc phosphate on the surface and then forming a layer of molybdenum phosphate on that layer.
The applicant has found that the excellent performance of coatings having the above loadings of molybdenum and phosphorus was achieved without the need to 4.5
S
S.
COMS ID No: SMBI-00424800 Received by IP Australia: Time 09:34 Date 2003-09-22 22/09 2003 09:29 FAX 61 3 92438333 GRIFFITH HACK IPAUSTRALIA ~007 4 ensure that the molybdenum in the solution had an oxidation state less than +6 and without the use of reducing agents in the solution to achieve this outcome, as is the case with International application PCT/US97/00012 (W097/27001).
In any given situation, the amounts of molybdenum and phosphoric acid that are necessary to obtain the product loadings of at least 10 mg/n 2 molybdenum and at least 15 mg/m 2 phosphorus depends on a range of factors, such as, by way of example, the zinc concentration of the Al/Zn alloy, pH of the solution, and the thickness of the final coating.
Preferably the Al/Zn alloy contains 25-75 wt.% aluminium.
More preferably the Al/Zn alloy is aluminium rich.
Preferably the surface coating formed in step (i) is 3-5 micron thick.
The surface coating may be formed by' any suitable means.
By way of example, the coating may be formed by applying the solution to the A1/Zn alloy surface by means of a roller-coater.
30 Alternatively, the coating may be formed by firstly dipping the Al/Zn alloy surface into a bath of the solution or spraying the solution onto the surface to form a coating having a thickness greater than 5 micron and thereafter removing excess solution by means o a squeegee roller or other suitable means.
The solution may be applied to the Al/Zn alloy oo*er o** o• o *o o COMS ID No: SMBI-00424800 Received by IP Australia: Time 09:34 Date 2003-09-22 22/09 2003 09:30 FAX 61 3 92438333 01 GRIFFITH HACK G IPAUSTRALIA oo008 surface at any suitable temperature.
Preferably the solution application is less than temperature Preferably the pH of the solution is less than 3 when it is initially applied to the Al/Zn alloy surface.
More preferably the pH of the solution is less than 2.6 when it is initially applied to the Al/Zn alloy surface.
The coating formed in step may 1 any suitable means in step (ii) that ensures thoroughly dried.
Preferably step (ii) includes dryin< formed in step at temperatures of at leas >e dried by :he coating is Sthe c 60 0
C.
oating More preferably step (ii) includes drying the coating formed in step by induction heating.
I
Preferably, the dried coating formed in step (ii) is 20-100 nanometers thick.
a.* a.* a a
C.
C
a More preferably the dried coating is nanometers thick.
Preferably the molybdenum loading of 30 coating is at least 15 gm/m 2 of the coating.
Preferably the phosphorus loading of is at least 20 gm/m of the coating.
30-50 the dried the coating Preferably the Al/Zn alloy is a coating on a a e ft f tt t f f f ft ft ft ft f ft ft COMS ID No: SMBI-00424800 Received by IP Australia: Time 09:34 Date 2003-09-22 WO 99/61681 PCT/AU99/00419 6 steel strip.
Preferably the coating is continuous.
Preferably the solution contains 5-30 g/l molybdenum.
Preferably the g/l molybdenum.
solution contains at least 13.5 Preferably the solution contains less than 20 g/l molybdenum.
Preferably the molybdenum is added as a salt.
Preferably the molybdenum salt is ammonium molybdate.
Other suitable and potassium molybdate.
molybdenum salts include sodium Preferably the phosphoric acid is concentrated phosphoric acid. The term "concentrated" is understood to mean that the acid is in the form of an aqueous -solution in which at least 80 volume% of the solution is acid and less than 20 volume% is water.
Preferably the solution contains 2-10% by volume of the phosphoric acid.
More preferably the solution contains at least 3 volume% of the phosphoric acid.
It is preferred particularly that the solution contain at least 4 volume of the phosphoric acid.
Preferably the phosphoric acid is orthophosphoric WO 99/61681 PCT/AU99/00419 7 acid.
Preferably the surface etchant is a fluorine containing compound, such as sodium fluoride.
Preferably the solution contains at least 0.3 g/l fluorine.
More preferably the solution contains at least 0.5 g/1 fluorine.
The solution may contain other constituents.
Preferably, the solution contains up to 5 g/l vanadium.
According to the present invention there is also provided an A1/Zn alloy surface treated in accordance with the above-described anticorrosion treatment.
According to the present invention there is also provided a solution for use in the above-described anticorrosion treatment which includes 5-40 g/1 molybdenum, 2-19% by volume of a phosphoric acid, and an etchant.
Preferably the molybdenum in the solution has an oxidation state of +6.
Preferably the solution contains 5-30 g/l molybdenum.
More preferably the solution contains at least 13.5 g/l molybdenum.
More preferably the solution contains less than g/l molybdenum.
WO 99/61681 PCT/AU99/00419 8 In order to investigate the performance of the present invention the applicant carried out a series of wet stack laboratory experiments on aluminium/zinc panels treated with the range of treatment solutions summarised in Table 1.
In order to simulate conditions expected in a commercial production line the treatment solutions were applied by dipping the panels for 4 seconds in the treatment solution and then sheen spinning excess solution.
The coatings on the panels were then thoroughly dried using a convection air drier.
The molybdenum, vanadium, phosphorus and fluorine in the treatment solutions used in samples 2-8 were added as ammonium molybdate, ammonium vanadate, orthophosphoric acid, and sodium fluoride respectively. The orthophosphoric acid was either 81 or 85% aqueous orthophosphoric acid.
The pH of the treatment solutions varied between and 2.2.
The dried coatings of samples 2-8 were-20-100 nanometers thick. The dried coatings of samples 2-4 had loadings of molybdenum and phosphorus above 10 and mg/m 2 respectively. The dried coating of sample 5 had loadings of molybdenum and phosphorous above 10 and 17 mg/m 2 respectively.
The wet stack experiments were carried out over a 4 week period and at 40 0
C.
Details of the colour and corrosion resistance of each panel and the conclusion of the wet stack experiments are set out in Table 1.
TABLE 1 Sample Treatment solution Colour After 24 Hours After Corrosion Resistance Pass or Fail No Passivation Corrosion Test 1 Chromated aluminium/zinc alloy Clear No sign of corrosion Pass 2 27 gIL Mo,0.5 gIL V,lo'sHlP0 4 (45.6 g/L Blue a green. Colour varied No sign of black staining. 5%s of red Pass 0.4 g/L P,pH 1.5 at edges considerably rust on cut edges 3 13.5 g/L Mo,2 g/L V,5Wi3PO, (45.6 gIL Light tan, no colour No sign of black staining. 5%s of red Pass 0.7 g/L F,pH 1.5 variability rust on cut edges 4 13.5 g/L Mo,0 g/L V,5'sH3PO& (22.8 g/L Very light tan, no colour 5%s black staining (very light grey in Pass 0.7 g/L P variability colour). 5-10%s red rust around the cut edges 13.5g/L Mo, 2g/LV,2'sH,P0 4 (9.1 g/L Light tan, no colour No sign of black staining. 15-20%s Pass 0.7 g/L F, pH 1.9 variability white/grey corrosion 6 13.5 g/L Mo,2g/L V,5'sHP0, (22.8 gIL Light tan 100%s black staining and 100%s red rust on Fail Og/L F cut edges. Note 2/6 panels had no sign of black staining (problem with variability) 7 8g/L Ho, lg/L V,l.5'sH3P0 4 (22.8 g/L Clear 100's black staining and 100%s red rust on Fail Og/L F cut edges a 5.4g/L Mo,lg/L V,l.5'sH 3 POj (22.9 g/L clear 100%s black staining and 100%s red rust on Fail 0.2g/L P cut edges 9 untreated aluminium/zinc alloy clear 100's black staining. 100%s red rust on Pail I ocut edgesI WO 99/61681 PCT/AU99/00419 It is clear from the table that the treated panels of samples 3-5 in accordance with the present invention had comparable colour and samples 2-3 had comparable corrosion resistance to the chromated aluminium/zinc alloy panel of sample 1 and significantly better corrosion resistance than the treated panels of panels 6-8 and the untreated aluminium/zinc alloy panel of sample 9.
The applicant also carried out trials on aluminium/zinc alloy strip using the solutions of samples 2, 3 and 4 on a commercial production line of the applicant at Pt Kembla, Australia. Solutions 2 and 3 were each applied by 2 separate methods, namely spray squeegee and roller coater, and then the coatings were dried by hot air (in the case of spray squeegee coatings) and induction heating (roller coater). Solution 4 was applied using a spray squeegee and the coating was dried by hot air.
Production runs of at least 3 tonnes were produced for each solution. Samples of each production run were wet stacked at 40 0 C. After four weeks the corrosion resistance results were consistent with the results presented in Table 1. In particular, samples from the production runs for solutions 3 and 4 exhibited no colour variability.
Although the invention has been described with reference to specific examples, it would be appreciated by those skilled in the art that the invention may be embodied in many other forms.
Claims (11)
1. An anticorrosion treatment of an aluminium/zinc alloy surface which includes the steps of: forming on the surface a coating of a chromium-free solution which contains 5-40 grams of molybdenum per litre of the solution, with the molybdenum having an oxidation state of 2-19% by volume of a phosphoric acid, and a surface etchant; and (ii) drying the coating to form a dried coating having a loading of molybdenumlof at least 10 mg/m 2 of the dried coating and of phosphorus of at least 15 mg/m of the dried coating.
2. The treatment defined in claim i wherein the Al/Zn alloy contais 25-75 wt.% aluminium.
3. The;treatment defined in claim 2 wherein the Al/Zn alloy is aluminium rich.
4. The.treatment defined in any o!e of the preceding claims wherein step includes forming the surface coating by:applying the solution to the Al/Zn alloy surface at a solution application temperature of less than 350C.
5. The ;treatment defined in any one of the preceding claims wherein the pH of the solutio is less than 3 when it is initially applied to the Al/Zn alloy surface. I
6. The treatment defined in claim 5 wherein the pH of the solution is less than 2.6 when it is initially N:\Icrct\XKnp\eeci\BK\Amu ANTICDRZOeiOH T MENT.coc 1S/0/03 9 COMS ID No: SMBI-00424800 Received by IP Australia: Time 09:34 Date 2003-09-22 22/09 2003 09:30 FAX 61 3 92438333 0 GRIFFITH HACK IPAUSTRALIA o010o 12 applied to the AI/Zn alloy surface.
7. Thei treatment preceding claims wherein the molybdenum.
8. The treatment preceding claims wherein the
13.5 g/l molybdenum. .0 9. The: treatment preceding claims wherein the g/1 molybdenum. defined in any o: solution containi ie of the 5-30 g/1l defined in any one of the solution contains at least defined in any o solution contain ie of the less than The:treatment claims wherein the defined in any one of the solution contains 2-10% by preceding volume of the phosphoric acid. preceding by volume 11. Theitreatment defined in any 0o claims wherein the solution contain of the phosphoric acid. Le of the i at least 4% 12. The treatment defined in any o01 preceding claims wherein the surface etchant containing compound and the solution contains g/1 fluorine. of the a fluorine- least 0.3 13. The,treatment defined in claim 12 wherein I the solution contains at least 0.5 g/l fluorine.
14. The treatment defined in any one of the preceding claims wherein the solution contains up to 5 g/1 vanadium. An Al/Zn alloy surface that ha4 been treated in accordance with:the anticorrosion treatment defined in any one of the preceding claims. x,\Bkrot\Knp\evel1\BHP\M AMTICORRCEO0N Tran.mT.d0 19/09/03 00 f COMS ID No: SMBI-00424800 Received by IP Australia: Time 09:34 Date 2003-09-22 22/09 2003 09:30 FAX 61 3 92438333 0 GRIFFITH HACK 4 IPAUSTRALIA Q011 13
16. A chromium-free solution for ul anticorrosion treatment defined in any one of 14, which solution includes 5-40 g/1 molybdeni molybdenum having an oxidation state of 2, of the phosphoric acid, and the etchant. Dated this 22nd day of September 2003 BHP STEEL (JLA) PTY LTD By their Patent Attorneys GRIFFITH HACK Fellows Institute of Patent and Trade Mark Attorneys of Australia se in the claims 1 to im, with the -19% by volume 9* 9999 9 99 9* 9 9* \\neltilein\homs\klt\Emp\apeci\BBP\n JTfICORROSION laT ET.aoc 1i/09/03 COMS ID No: SMBI-00424800 Received by IP Australia: Time 09:34 Date 2003-09-22
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
AU41242/99A AU767358B2 (en) | 1998-05-28 | 1999-05-28 | An anticorrosion treatment |
Applications Claiming Priority (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
AUPP3751A AUPP375198A0 (en) | 1998-05-28 | 1998-05-28 | An anticorrosion treatment |
AUPP3751 | 1998-05-28 | ||
PCT/AU1999/000419 WO1999061681A1 (en) | 1998-05-28 | 1999-05-28 | An anticorrosion treatment |
AU41242/99A AU767358B2 (en) | 1998-05-28 | 1999-05-28 | An anticorrosion treatment |
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AU4124299A AU4124299A (en) | 1999-12-13 |
AU767358B2 true AU767358B2 (en) | 2003-11-06 |
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AU41242/99A Expired AU767358B2 (en) | 1998-05-28 | 1999-05-28 | An anticorrosion treatment |
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Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3697332A (en) * | 1971-02-11 | 1972-10-10 | Amchem Prod | Method for coating aluminum while avoiding objectionable wastes |
US4264378A (en) * | 1979-02-14 | 1981-04-28 | Oxy Metal Industries Corporation | Chromium-free surface treatment |
US4775427A (en) * | 1986-09-18 | 1988-10-04 | Gerhard Collardin Gmbh | Phosphate conversion coatings for composite metals |
-
1999
- 1999-05-28 AU AU41242/99A patent/AU767358B2/en not_active Expired
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3697332A (en) * | 1971-02-11 | 1972-10-10 | Amchem Prod | Method for coating aluminum while avoiding objectionable wastes |
US4264378A (en) * | 1979-02-14 | 1981-04-28 | Oxy Metal Industries Corporation | Chromium-free surface treatment |
US4775427A (en) * | 1986-09-18 | 1988-10-04 | Gerhard Collardin Gmbh | Phosphate conversion coatings for composite metals |
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AU4124299A (en) | 1999-12-13 |
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