United States Patent 1191 'Evans Oct. 8, 1974 1 INSULATIVE COATINGS FOR 3,144,364 8/1964 Robinson 6:111. l48/6.l5 z ELECTRICAL STEELS g [75] Inventor: James D. Evans, Middletown, Ohi 3:395:052 7/1968 Yonezaki et a]. l48/6.i5 z Assignee: Armco Steel Corporation, 3,644,152 2/1972 Schlossberg et aI. l48/6.l5 R
Middletown, Ohio P E L B H rzmar'y xammerorenzo ayes [22] 1972 Attorney, Agent, or Firm-Melville, Strasser, Foster & [21] Appl. No.: 237,344 Hoffman Related U.S. Application Data [63] Continuation-impart of Ser. No. 39,649, May 22, ABSTRACT 1970 abandoned lnsulative coatings for electrical steels having improved resistance to deteriorationduring stress relief 106/14 anneals or other heat treatments carried on in reducg n e 6 6 a e 6 6 e a I 6 u a a e e n u 6-. n I 6 s e e n I e 6 6 e s u I [58] new of 106/14 148/6'15 2 2 electrical steel with an aqueous solution of phosphoric acid, magnesium oxide and one or more additional 56] References Cied mineral acids present in an amount sufficient to adjust the pH level of the solution to from about 0.5 to about UNITED STATES PATENTS 3.0. The mole ratio Mg/PO should be from about 0.6 2,233,422 3/1941 Lodeesen l48/6.l5 Z to about 1.5. 2,50l,846 3/1950 Gifford l48/6.l5 R 2,975,082 3/1961 Henricks 148/6.i5 Z 6 Claims, 2 Drawing Figures A EXAMPLEI a g 1.0. EXAMPLEH o 1 .2 a :4 .5 .e .7 .5 19 1.0 1.1 1,2 1 3 1.4 1.5
MOLE RATIO MgO/PO INSULATIVE COATINGS FOR ELECTRICAL STEELS CROSS-REFERENC E TO RELATED APPLICATION This is a continuation-in-part of the copending application of the same inventor, Ser. No. 39,649 filed May 22, 1970, entitled INSULATIVE COATINGS FOR ELECTRICAL STEELS, and now abandoned.
- BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to improved insulative coatings for electrical steels, and more particularly to phosphate based insulative coatings resistant to deterioration during heat treatments in reducing atmospheres.
2. Description of the Prior Art As used herein and in the claims the terms electrical steel or silicon steel relates to an alloy the typical composition of which by weight'percent falls within the following:
Carbon 0.060% maximum Silicon 2 4% Sulfur or Selenium 0.03% maximum Manganese 0.02 0.4% Aluminum 0.04% maximum Iron balance At the present time, there is a great demand for silicon steels of sheet gauge for magnetic uses such aslaminated cores for transformers and the like.
Magnetic cores, such as are used in power transformers and the like, require high interlamination resistivity.
Much work has been done in this field to provide surface resistivity on electrical steels.
In the production of certain oriented grades of silicon steel a mill glass is formed during the high temperature anneal. Much work has been done toward the improvement of the insulative qualities of mill glass, as is exemplified in US. Pat. No. 2,385,332.
In some applications it is desirable to have an applied insulative coating rather than or in addition to the mill glass formed during the high temperature anneal. The need for an insulative coating which may be applied by the steel producer, so that the manufacturer may begin with sheets or coils having high surface resistivity, has led to the development of phosphate coatings. US. Pat. Nos. 2,501,846 and 2,492,095 are exemplary of such coatings. These phosphate coatings have been used with great success.
However, the manufacturer of electrical instrumentalities from silicon steel often requires that the silicon steel be subjected to a stress relief anneal or other heat treatment. Such stress relief anneals are frequently carried out at temperatures of from about 1,450F. to about 1,600F. (788C. to 871C.) in reducing atmospheres such as dry atmospheres containing 95 percent nitrogen and 5 percent hydrogen. Prior art phosphate coatings will demonstrate severe deterioration with respect to surface resistivity at temperatures as low as 1,200F. (649C.) when the annealing atmosphere contains more than 2 percent hydrogen.
The present invention is based upon the discovery that phosphate based insulative coatings for electrical steels, with or without a mill glass base coating, will resist deterioration in reducing atmospheres if a mole ratio Mg/PO is maintained at from about 0.6 to about 1.5 and preferably from about 0.7 to about 1.3. The coatings of the present invention include one or more additional mineral acids so as to maintain the pH level in the range of from 0.5 to 3.0 and preferably from about 1 to about 2 for the final solution.
SUMMARY OF THE INVENTION The present invention contemplates the provision of improved insulative coatings for oriented electrical steels with or without a mill glass base coating through the application of aqueous solutions of phosphoric acid, magnesium oxide and one or more additional mineral acids such as sulfuric or nitric acids.
In accordance with the present invention, the mole ratio Mg/PO, is maintained in the range of from about 0.6 to about 1.5 and'preferably from about 0.7 to about 1.3. The mineral acid is added to the mixture until the pH level is adjusted to the range of from about 0.5 to about 3.0, and preferably from about 1 to about 2.
In the above mentioned procedure, the mineral acids may be replaced by the magnesium salts thereof, provided that an adjustment is made in the magnesia addition to preserve the critical ratio.
The coating solutions of the present invention may be applied to the silicon steel (with or without a mill glass base coating) in any suitable and conventional manner. The coated silicon steel will be subjected to a heat treatment so that the final coating of the present invention will be formed thereon. This heat treatment is not to be confused with the final high temperature anneal given to silicon steel to develop grain orientation. Such a high temperature anneal would occur prior to the application of the coatings of the present invention.
BRIEF DESCRIPTION or THE DRAWINGS FIGS. 1 and 2 comprise graphs plotting the change in resistivityduring stress relief annealing against the molar ratio Mg/PO in the coating solution.
DESCRIPTION OF THE PREFERRED EMBODIMENTS The coatings of the present invention are particularly suitable for use with oriented silicon steels of the cube on-edge variety, but may be used with silicon steels of other orientations. When used with cube-on-edge oriented-silicon steels, the coatings may be applied either on the .bare metal (the mill glass base coating having been removed), or over a mill glass which formed during the high temperature anneal. In the practice of the present invention the coating solution should have a mole ratio Mg/PO, in the range of from about 0.6 to about 1.5 and preferably in the range of from about 0.7 to about 1.3. The pH level of the final solution should fall withinthe range of from about 0.5 to about 3.0 and preferably within the range of from about 1 to about 2.
When in the prior art, as exemplified by the above mentioned US. Pat. No. 2,501,846, magnesia was added to an aqueous solution of phosphoric acid in quantities to be wholly dissolved by the acid, a solution resulted having a pH of approximately 3 or less and a Mg to PO.,' mole ratio of about 0.5 or less. This is true because about 0.455 (or, in round numbers, about 0.5) is the theoretical maximum mole ratio achievable in such a solution. If, to obtain a higher mole ratio, one were simply to add more magnesia, the mole ratio of the system would go up but the mole ratio of the solution would not. While the pH of the solution would go up, the mole ratio would not due to formation of MgHPO which is insoluble in water when the pH is above about 4 or 5.
There are two primary ways in which the mole ratio and pH values required by the present invention may be achieved. First, to an aqueous solution of magnesia and phosphoric acid and additional quantity of magnesia may be added together with one or more mineral acids such as sulfuric acid or nitric acid. The mineral acids are preferably volatile at a relatively low temperature.
The mole ratio Mg/PO should be maintained in the range of from about 0.6 to about 1.5 and preferably in the range of from about 0.7 to about 1.3.
The mineral acid or acids are added until the pH level of the final solution falls within the range of about 0.5 to about 3.0 and preferably from about 1 to about 2. The purpose of adding the mineral acid is primarily to provide sufficient acidity to dissolve the metal phosphate. Variation of the acid content of the coating solutions of the present invention can be obtained by adding more or less mineral acid. Halogen acids, such as hydrochloric, may be used on bare steel butthey are not recommended where a glass coating has previously been formed because they attack the glass and prevent the applied coating from having good adherence and good resistivity.
A second way of achieving the desired mole ratio and pH values of the present invention entails the addition to the aqueous solution of magnesia and phosphoric acid of a magnesium salt of a mineral acid such as sulfuric acid or nitric acid. This is substantially the equivalent of adding magnesia and the mineral acid as in the first instance. This is true because when, for example, magnesia and nitric acid are combined magnesium nitrate (the magnesium salt of nitric acid) is formed together with water. The formation of water is not important (there being water already in the system) except with respect to the desired concentration of the final solution as dictated by the desired coating weight and coating method. When this second method is used the pH of the solution will remain substantially unchanged and will fall within the desired range. It will be understood that the addition of a mineral acid salt other than a magnesium salt would be extraneous to the system and would not make the required Mg addition to achieve the desired mole ratio value.
The coating solutions of the present invention may be mixed and applied by the same procedures heretofore practiced with respect to prior art phosphate coatings. For example, excellent results were achieved when the solutions were mixed in the following manner. A magnesia slurry (magnesia in distilled water) was slowly added to the equivalent of percent phosphoric acid until a precipitate appeared. Then a mineral acid, such as sulfuric or nitric acid, was added to dissolve the precipitate. Thereafter, more slurry was again added. This procedure was continued until all of the magnesia slurry had been added and enough mineral acid had been added to dissolve any precipitate which had formed.
The coating solutions of the present invention may be as dilute as desired for controlled application to the surfaces of the silicon steel sheet or strip. The solutions may be applied in any suitable manner including spraying, a'ippifig'ar s wabbin g. Metering rollers and doctor means may also be used. It has been determined that concentrated solutions, containing less than 40 percent of the total solution weight as water, tend to produce powdery coatings and are not easily applied by grooved wringer rolls. The upper limit of the percentage of the total solution weight as water is dictated only by the desired coating weight and the coating method used and can readily be ascertained by one skilled in the art to meet his particular needs.
-lt will'be understood by one skilled in the art that prior to the application of the solutions, the silicon steel sheets'or strips should be mechanically or chemically cleaned, so as to be free of oils, greases and scale. After coating, the silicon steel sheets or strips are dried and then subjected to a heat treatment in order to produce the final insulative coating. This heat treatment can be conducted at a temperature of from about 800F. to about 1,600F. (427? to 871C.) for from about minute to about 5 minutes in a dry non-oxidizing atmosphere, or at a temperature of from about l,200F. to about 1,600F. (649 to 871C.) in air,'if the coating is applied over a mill glass. The drying may be performed in a separate step orit may occur during the preliminary heating portion of the heat treatment just described. g
Analyses of the final fired coatings of the present invention reveal the presence of magnesium orthophosphate, which is very stable, insoluble and resistant to hydrogen reduction. Other forms of magnesium phosphate and other compounds may be formed, depending upon the mineral acids added.
EXAMPLE I Nineteen samples of 9-mil thick cube-on-edge oriented silicon steel having a mill glass base coating were cleaned to remove any oils, greases or scale. Thereafter, the samples had applied thereto coatings having a ratio Mg/PO ranging from 0.35 to 1.45. The coating solution compositions are given in Table I.
' TABLE 1* Coating Compositions as of Total Solution Weight I Sample Mole Ratio Number MgO H -,PO HNO H 50 H O Mg/PO TABLE I Continued Coating Compositions as 7r of Total Solution Weight For all solutions t heMg G slurry(MgO in water) was '7 1n ETC. 1, the solid line shows the correlation beslowly added to the equivalent of 75 percent H PO until a precipitate appeared; then H 50 or l-lNO was added to dissolve the precipitate and more slurry was again added. This type of addition was continued until all the MgO has been added and enough mineral acid has been added to dissolve any'precipitiate which had formed. The pH values determined for 11 of the solutions of Table 1 varied between 0.9 and 2.1. The pH values of the remaining solutions would be expected to fall within this range.
The strips were coated by immersing them in the solutions and passing them through wringer rolls having 43 grooves per inch 1-2 mil deep. The coated strips were predried 1 to 2 minutes in air at 600F. (316C.) and after coiling were fired in air at 1,450F. (788C) for 1 minute.
tween the change in resistivity during the stress relief anneal and the molar ratio of Mg to P0, in the coating solution. From FIG. 1 it will be evident that if the molar ratio is kept within the ranges given above. the change in resistivity is small. Samples 1 through 5 are exemplary of prior art coatings as taught in the above mentioned U.S. Pat. No. 2,501,846.
EXAMPLE 11 Four samples were taken from each of five different 1 l-mil thick coils of cube-on-edge oriented silicon steel. The samples, numbered 20 through 23, were hard pickled to remove the mill glass base coating on the silicon steel.
Four coating solutions were made up having the compositions given in Table 111 below.
Franklin resistivity tests were made after shearing into Epstein samples and again after a stress relief anneal at 1,450F. (788C.) in an atmosphere comprising 95 percent nitrogen and 5 percent hydrogen with a 2- hour soak. The test results are given in Table 11 below.
TABLE II 7 0 I HNO conc.. 180 gm MgO The samples were coated with the solutions at room temperature, dried at 600F. (316C.) for to seconds in air and cooled to room temperature.
Firing of the coatings was carried out in the strip furnace using a dry nitrogen atmosphere anda Bunsen RESISTlVlTY TESTS OF SAMPLES OF TABLE 1 Sample Mole Ratio Ave. Franklin Resistivity (Amps at 300 psi) Number Mg IPO. 1
Before SRA After SRA Change burner flame curtain to protect the entrance end of the furnace. The samples were fired at 1,500F. (816C.) for l to 1 minutes. One-fourth inch was sheared from each edge of the samples to remove heavy coating.
Franklin resistivity measurements at 300 psi were taken at four positions on each sample both as cut and after a stress relief anneal at 1,450F. (788C.) for 2 hours in a dry 95 percent nitrogen 5 percent hydrogen atmosphere. The test results are given in Table IV below. Again, coating solution A is exemplary of those taught in US. Pat. No. 2,501,846.
The results are graphically illustrated by the broken line in FIG. 1. It will be noted that the coatings having TABLE IV As in Example I], firing of the coatings was carried out in the strip furnace using a dry nitrogen atmosphere and a Bunsen burner flame curtain to protect the entrance end of the furnace. The samples were fired at 1,500F. (816C.) for 1 to 1 /2 minutes. Again onefourth inch was sheared from each edge of the samples to remove heavy coating.
Franklin resistivity measurements at 300 psi were taken at four positions on each sample both as cut and after a stress relief anneal at 1,450F. 788C.) for 2 hours in a dry 95 percent nitrogen 5 percent hydrogen atmosphere. The test results are given in Table VI below.
RESISTIVITY TESTS OF SAMPLES OF TABLE 111 Sample Mole Ratio Ave. Franklin Resistivity (Amps at 300 psi) Number Mg/PO Before SRA After SRA Change .3 .14 .38 .24 21 .7 .14 .l l .03 22 .7 .28. .18 .1O 23 1.5 .44 .46 .02
& mafia RESISTIVITY TESTS OF SAMPLES OF EXAMPLE III I Sample Mole Ratio Ave. Franklin Resistivity (amps at 300 psi) Number Mg IP0 Before SRA After SRA Change EXAMPLE Ill Samples were taken from another 1 l-mil thick coil of cube-on-edge oriented silicon steel. Again the samples were hard pickled to remove the mill glass base coating therefrom.
The samples, numbered 2 through 29, were coated, dried and fired in the same manner as described in Example ll. Samples 24 through 27 were provided with the same four coatings of Example II. Samples 28 and 29 were provided with two additional coatings having compositions given in Table V below.
TABLE V Mole Sample Coating Ratio Num- Solution Mg/PO Composition of Solution her 28 E .5 I 130cc H O. 625cc 85% H PO cone, 180 gm MgO 29 F .5 1l30cc H O. 625cc 85% H PO 50cc HNO conc., 180 gm MgO The results are graphically illustrated by the broken line in FIG. 2. Again the results of Example I appear as a solid line in FIG. 2 for purposes of comparison. It will again be noted that the coatings have a mole ratio of Mg/PO within the ranges given above significantly prevented a loss of resistivity during the stress relief anneal.
The as cut resistivities of the samples of Example III, when compared to those of the samples of Example II, indicated that heavier coatings were produced in Example III. It is believed that these heavier coatings caused the shift of the curve of Example III to a position more nearly equal to the curve of Example I.
The Examples above clearly illustrate that the stability of the coatings during the stress relief anneal depends on the mole ratio Mg/PO and that those coatings having a ratio within the above given ranges result in improved resistivity of the oriented silicon steel after a stress relief anneal both when they are applied to the bare steel and when they are applied over a mill glass base coating. 7
In general, the solution of the present invention should contain in weight percent no less than about 40 percent water; no less than about 2 percent H PO in the solution; no more than about 45% H PO in the solution; and no more than about percent H PO in the solution, calculated on a water-free basis.
A number of modifications may be made in the in vention without departing from the spirit of it. For example, inert fillers, both soluble and insoluble, may be added to the solution to produce more body and thereby achieve thicker films and better resistivity. Exemplary inert fillers which may be used include collodial SiO mica, Cr O TiO ZrO and the like. Ad-
dition of colloidal silica requires close pH control to prevent gelation of the colloid.
It will be understood by one skilled in the art that the final coating of the present invention may be produced by substituting magnesium phosphates for the phosphoric acid and magnesia. For example, an initial solution could be prepared from mono-basic magnesium phosphate and magnesia. Since the ratio Mg/PO would be 0.5, magnesia should be added to increase the ratio. lf di-basic magnesium phosphate is used, the ratio of 1.0 would be satisfactory without adding magnesia or phosphoric acid. However, if tri-basic magnesium phosphate is used, the ratio of 1.5 is undesirably high and additional phosphoric acid would be needed. in all cases mineral acid would be necessary to dissolve the solids and adjust the pH within the aforementioned ranges.
Furthermore, while the preferred form for introducing magnesium into the coating is magnesia powder, which becomes magnesium hydroxide when mixed with water, magnesium hydroxide may be added initially in place of all or part of the magnesia.
Modifications may be made in the invention without departing from the spirit of it.
The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:
1. A composition for forming an insulative coating directly-on oriented silicon steel for electrical uses and an oriented silicon steel having a mill glass thereon, said composition comprising anaqueous solution having a Mg/PO ratio of from about 0.6 to about 1.5, said solution consisting essentially of an aqueous solution of phosphoric acid, magnesia, and at least one substance chosen from the class consisting of sulfuric acid, nitric acid and magnesium salts thereof, said substance being present in an amount sufficient for said solution to have a pH of from about 0.5 to about 3.0.
2. The composition claimed in claim 1 wherein said mole ratio is from about 0.7 to about 1.3.
3. The composition claimed in claim 1 wherein said substance is present in an amount sufficient for said solution to have a pH of from about 1 to about 2.
4. A composition for forming an insulative coating directly on oriented silicon steel for electrical uses and an oriented silicon steel having a mill glass thereon, said composition comprising an aqueous solution having a Mg/PO radical mole ratio of from about 0.6 to about 1.5, said solution consisting essentially of an aqueous solution of compounds chosen from the class consisting of mono-basic magnesium phosphate plus magnesia, di-basic magnesium phosphate, tri-basic magnesium phosphate plus phosphoric acid and magnesia plus phosphoric acid,'plus at least one substance chosen from the class consisting of sulfuric acid, nitric acid and magnesium salts thereof, said substance being present in an amount sufficient for said solution to have a pH of from about 0.5 to 3.0.
5. The composition claimed in claim 4 wherein said mole ratio is from about 0.7 to about 1.3.
6. The composition claimedin claim 4 wherein said substance is present in an amount sufficient for said solution to have a pH of fromabout l to about 2.