US3583887A

US3583887A - Magnesium oxide coating composition and process

Info

Publication number: US3583887A
Application number: US850910A
Authority: US
Inventors: John F Steger; Jay W Palmer
Original assignee: Morton International LLC
Current assignee: Morton International LLC
Priority date: 1969-08-18
Filing date: 1969-08-18
Publication date: 1971-06-08
Anticipated expiration: 1988-06-08
Also published as: BE754777A; FR2058056A5; SE356766B; DE2041051A1

Abstract

MAGNESIUM OXIDE COATING COMPOSITIONS AND PROCESS FOR APPLYING TO SILICON-CONTAINING MAGNETIC STEEL AN ADHERENT COATING WHICH ACTS AS A SEPARATING MEDIUM TO PREVENT FUSING OR WELDING OF COILED SHEET DURING AN ANNEALING PROCESS AND WHICH COATING PROVIDES ELECTRICAL INSULATIING AND CORROSION RESISTANT PROPERTIES. THE COATING COMPOSITIONS COMPRISE A MAJOR PROPORTION OF MAGNESIUM OXIDE AND A MINOR PROPORTION OF ADDITIVES CONTAINING A BORON COMPOUND, A SODIUM COMPOUND, AND SILICA OR A SILICON-CONTAINING COMPOUND.

Description

June 8, 1971 J. F. STEGER ETAL 3,583,887

MAGNESIUM OXIDE COATING COMPOSITION AND PROCESS Filed Aug. 18, 1969 q N Q as B Q f 3 if!) U) Q N w 5 LU 2U \lq (\I :5; w 5 V") q.

I 21 ru 2 0 q 5 m 6 m 5% S 5 6 255 Q 5 5% Q q$ u Q1 O N INVENTORS JOHN F. STEGEFB JAY W PALMER Q M/)/AZW ATYYS United States Patent Office 3,583,887 MAGNESIUM OXIDE COATING COMPOSITION AND PROCESS John F. Steger and Jay W. Palmer, Crystal Lake, 111., assignors to Morton International, Inc., Chicago, Ill. Filed Aug. 18, 1969, Ser. No. 850,910 Int. Cl. B23b 15/04; H01f N04 US. Cl. 14827 15 Claims ABSTRACT OF THE DISCLOSURE BACKGROUND OF THE INVENTION Field of the invention Electrical transformers and other types of electrical induction apparatus are made using core materials made from steel sheet having soft magnetic properties. Such sheet is prepared by cold-rolling silicon-containing steel into sheet form, coiling the steel sheet into rolls and thereafter annealing the coiled steel by a controlled heating process to produce a grain oriented structure having desirable magnetic properties.

Magnesium oxide is used extensively as a highly heat resistant separator medium and protective coating for metal surfaces. It is also used as an electrical insulator coating for metals, as a gatherer for removing impurities, such as sulfur and carbon, from thin metal sheets and particularly as a protective coating for silicon steel. The electrical insulating coating is understood to be derived from coating magnesium oxide on steel, which then forms a film or coating containing Mg SiO which coating is an effective electrical insulator when annealed.

Description of the prior art According to the present industrial practice, siliconcontaining steel is cold rolled into sheets, decarburized and thereafter coiled into convenient rolls. Cold rolling develops in the steel the potential to form a grain oriented structure when the steel is later annealed. The term annealed refers to a process whereby the steel is heated to about 1200 C. in an essentially pure hydrogen atmosphere (or vacuum) under programmed conditions with respect to time and temperature. This results in a growth in size of the steel grains and also in a specific grain orientation which provides the desired soft magnetic properties sought. During the annealing process, virtually all of the remaining excess carbon and sulfur content of the steel is lost. This type of annealing is known in the art as box annealing.

The steel so produced is in the form of a long, thin, coiled sheet which must be uncoiled and thereafter fabricated into the desired shape and size for its intended use. In the process of fabrication which can include, for example, punching, stamping and bending, strains and stresses are introduced in the steel which impair its magnetic properties. Consequently, the strains and stress must be relieved. This is accomplished by a process termed stress relief annealing which comprises reheating the fabricated steel to a temperature of about 800 C. in a ,1

reducing atmosphere for a specified period of time.

3,583,887 Patented June 8, 1971 During the box annealing process where the steel is in large coils, in the absence of a suitable separating medium, the coiled roll would fuse to itself and could not be unrolled. Conventionally, this is avoided by placing a thin coating of magnesium oxide on the steel prior to coiling. Further, the magnesium oxide coating serves to reduce impurities such as carbon and sulfur in steel by chemical reaction. In addition, magnesium oxide provides an insulating silicate layer by reaction with the silicon in the steel. There is also evidence that some iron silicate is formed. For certain applications, it is also important to form an efiicient electrical insulating coating. Thus, for example, transformer cores are constructed from thin sheets of soft magnetic steel stacked together to form a laminated body in which each sheet is electrically insulated from its neighbor. This construction vastly reduces the generation of eddy currents in the core imposed by an alternating electrical field. The average density of soft iron in the core should be as large as possible and consequently the insulation on the plates should be as thin as possible to provide closer stacking of steel plates.

Obviously, short circuits between plates reduces transformer efficiency and often causes the development of damaging hot spots in the transformer core. Consequently soft magnetic steel is rated by the number of short circuits per unit area, usually expressed in terms of the electrical resistance of the insulating layer. This is a standard ASTM measurement known as the Franklin Test.

Since stress relief annealing is sometimes conducted in an atmosphere of impure hydrogen containing hydrocarbons, moisture and oxygen, the surface of the steel beneath the insulating magnesium oxide layer is attacked forming inclusions of interstitial carbides and oxides thereby impairing the magnetic properties of the steel. This quite obviously is a serious problem which demands a particular type of insulation to preserve the necessary magnetic properties.

A further problem arises because magnesium oxide is applied to steel from an aqueous suspension or slurry. During the initial stages of the box annealing process, water volatilizes from an applied coating and can under ordinary conditions react with the iron on the surface of the steel forming current conducting iron oxides which impair the electrical insulating properties sought. Areas on the surface of the steel displaying such deleterious iron oxide formations are referred to in the art as anneal patterns. Furthermore, it has been found that magnesium oxide does not form an intimately bonded tightly adherent coating which is not easily removed upon contact.

It has been found that magnesium oxide per se fails to provide the desired high degree of required insulation and magnetic protection properties to overcome the noted defects. Accordingly, it would be desirable to provide magnesium oxide compositions for coating steel which compositions are tightly adherent and maintain suitable electrical insulating properties after box annealing and stress relief annealing, and which also preserve the desired magnetic properties of the steel after stress relief annealing.

It is therefore an object of the present invention to provide improved magnesium oxide compositions for coating silicon steel which compositions form electrical insulating barriers that prevent the formation of undesirable anneal patterns believed to be due to iron oxide formations during box annealing.

It is another object of the present invention to provide magnesium oxide compositions for coating silicon steel which compositions form adherent electrical insulating coatings which are also capable of preventing attack of the steel surface by impure hydrogen during stress relief annealing.

It is still another object of the present invention to provide magnesium oxide coating compositions for coating silicon steel which compositions have the above attributes and also function as eflicient separator media for coiled, rolled steel sheet.

It is a further object to provide a simplified process for coating steel sheet with said magnesium oxide compositions to achieve the aforementioned benefits.

The fulfillment of these and other related objects of this invention may be more readily appreciated by reference to the following specification, examples, and appended claims.

SUMMARY OF THE INVENTION Broadly, the above objects are accomplished by the provision of magnesium oxide coating compositions containing a major proportion of magnesium oxide, and a minor proportion of the additives:

The invention also provides a process for coating steel sheet with an adherent, electrical insulating, corrosionresistant coating comprising in sequence applying to the surface of said steel an aqueous slurry containing the said magnesium oxide coating composition, heating to remove water therefrom, and thereafter annealing the coated steel at a temperature in excess of about 1000 C.

The magnesium oxide employed has a surface area in excess of about 20 square meters per gram or an iodine number (iodine adsorption valve) in excess of about 24 milligrams of iodine per gram of dry magnesium oxide. The surface area of magnesium oxide as referred to herein is determined by the standard Brunaeur-Emmet-Teller method. The iodine number is approximately 1 to 1.25 times the surface area in square meters per gram.

The iodine number as referred to herein is determined by the following procedure:

METHOD OF IODINE NUMBER DETERMINATION (1) Weight a 2 gram sample of magnesium oxide to the nearest milligram.

(2) Transfer to a clear, dry, 200-ml. glass-stoppered bottle.

(3) Add 100:0.2 ml. of 0.100 N iodine in carbon tetrachloride, free from traces of sulfur or carbon disulfide.

(4) Stopper the bottle and shake vigorously at ambient temperature in a suitable shaking device for 30 minutes (the test is relatively insensitive to temperature so that no temperature controls are employed).

(5) Allow to settle for 5 minutes or longer and then pipette a 20 ml. aliquot of the clear solution into a 250 ml. Erlenmeyer flask containing 50 ml. of 0.03 N potassium iodide in 75 percent ethanol,

(6) Titrate the 20 ml. aliquot with standard 0.05 N sodium thiosulfate. The sodium thiosulfate should be standardized at least once every two weeks against a standard potassium iodate solution. A sharp end point is obtained without the use of starch indicator.

(7) Calculate iodine number in terms of milligrams of iodine per gram of sample according to the following equation:

where V is the volume of thiosulfate equivalent to 20 ml. of the original iodine solutionbefore adsorption of iodine by the oxide; where V is the volume of thiosulfate required by the 20 ml. aliquot after adsorption; and N is the normality of the thiosulfate solution.

By the term boric acids it is meant to include all of the various known boric acids, such as for example, but not limited to, metaboric acid, orthoboric acid and pyroboric acids.

By the term magnesium borates it is meant to include the various known magnesium borates, such as for example, but not limited to the magnesium orthoborates, the magnesium metaborates and the magnesium pyroborates.

By the term sodium borate it is meant to include all of the various known sodium borates, such as for example, but not limited to sodium tetraborate, sodium metaborate, and sodium orthoborate. Silica in virtually any form and having a particle less than about 200 mesh may be employed, such as the product available under the trade name Cabosil. Equally operable are the alkaline earth metal silicates, such as for example, calcium silicate and magnesium silicate.

Generally, the concentrations of additives, on a molar ratio basis, range as follows:

The molar ratio of magnesium oxide to silica is from about 280:1 to about 2900:1, preferably from about 1000:l to 2000:1;

The molar ratio of boron (expressed as B 0 to silica is from about 3:1 to about 5:1, preferably from about 3 :1 to 4:1;

The molar ratio of magnesium oxide to sodium is from about 2000:l to about 400011 with about 2800:l being preferred.

In the aggregate the additives (silica, boron and sodium, calculated as expressed above) in the coating composition may range up to about 2 /2 mole percent and are preferably present in amounts up to about 2 mole percent, based on the total moles of MgO and additives.

For coating steel, an aqueous suspension of the above described magnesium oxide composition is prepared by mixing with Water to the desired viscosity and leveling and flow-out characteristics. Generally from about 5 to about 20 Weight percent of the magnesium oxide composition, based on water, is satisfactory to provide an aqueous slurry having the requisite viscosity and flow properties suitable for coating onto steel sheet.

A frit may also be prepared by fusing magnesium oxide with a boron-containing compound, a sodium compound and a silicon-containing compound as hereinbefore described. The frit may then be comminuted to a particle size less than 200 mesh and added to Water to form the coating slurry. In preparing aqueous slurries of the coating compositions, the order of addition or admixture of the various components of the composition is immaterial.

The coating slurry may be applied to the magnetic sheet material by any suitable means such as by immersion, brushing, or spraying. It has been found convenient to use an immersion technique whereby the steel sheet is Passed through a tank containing the coating slurry, The coated sheet thereafter is heated to drive off water and provide a dried layer of the present composition. The coated metal sheet is then coiled into a roll and placed in a furnace for box annealing as previously described. During the annealing process, the coating of this invention forms an adherent, electrically insulating, corrosion-resistant layer which also functions as a separator medium to prevent the coiled metal sheet from sticking to itself.

BRIEF DESCRIPTION OF THE DRAWING The drawing is a schematic diagram of a conventional process for coating the compositions of the present invention on steel strip. As therein illustrated, a magnesium oxide composition contained in hopper 10 and water in tank 12 are fed via 13 and 13a to mixing tank 14 to form an aqueous coating suspension or slurry. The aqueous coating slurry is conducted through line 18 equipped with valve 20 to coating trough 22. Newly formed, hot steel sheet 23 is passed in the direction indicated by arrows over roller 24 and under roller 26 through quench tank 28 and thence over roller 25 and through coating trough 22 where it acquires a layer of the coating slurry. The steel sheet coated with an aqueous slurry of the coating composition is then passed between adjustable pinch rollers 30 which regulate the coating thickness and then to heater 32. In the heater, water is volatilized from the slurry layer on the steel strip to provide an adherent coating. The coated steel sheet is passed over roller 33 and coiled into suitable lengths at take-up roll 34. The coated coiled steel roll 23A is thereafter passed to annealing furnace 36, and thence to storage.

DESCRIPTION OF THE PREFERRED EMBODIMENTS In one preferred form, a steel coating composition comprising magnesium oxide, boric acid, sodium hydroxide, and silica is provided in which the molar ratio of magnesium oxide to silica is about 1500:l, the molar ratio of boric oxide to silica is about 3.521 and the molar ratio of magnesium oxide to sodium is about 2800:1. Approximately 10 to 12 Weight percent of this composition is admixed with water to form a slurry suitable for coating onto steel sheet. Coiled steel sheet which was coated with this slurry and subsequently dried and thereafter box annealed according to the procedure hereinbefore described was easily unrolled. Further, the surface of the steel was relatively electrically non-conducting and resistant to attack by corrosive gases or fumes.

In another preferred form a magnesium oxide composition having the aforenoted desirable steel coating properties is provided which comprises magnesium oxide, boric oxide, sodium tetraborate, and silica in which the molar ratio of MgO to silica is about 1500:1, the molar ratio of boric oxide to silica is about 3.5 :1, and the molar ratio of magnesium oxide to sodium is about 2800: 1.

For a more complete understanding of the present invention, reference is now made to the following specific examples illustrating the improved properties of the coating compositions of the present invention.

EXAMPLE 1 A steel coating suspension was prepared by adding 18.0 grams of MgO (0.45 mole) to 150 ml. of an aqueous boric acid solution containing 0.00105 mole of boron expressed as B To this suspension was added 0.00016 mole of sodium hydroxide and 0.0003 mole of silica having a crystallite size of about 70 A., to yield an aqueous coating composition of about solids containing the following components in the indicated ratios:

Coating Composition A: Molar ratio MgOzSiO 1500:1 B203 :SiO 1 MgOzNa 281221 Coating procedure The resultant suspension was subjected to constant stirring and was coated onto 26 separate silicon steel sheets or plates, each sheet measuring 3.0 x 15.3 cm. by 12-14 mils in thickness. The coatings were leveled and then dried in air at a temperature of about 500 C. The coated, dried sheets were then stacked one upon another and annealed by heating in a hydrogen atmosphere at a temperature of 1177 C. for a period of 4.3 hours. The annealed sheets were then cooled, and excess or loose magnesium oxide was scrubbed from the surface of each coated sheet by brushing in a stream of flowing water.

The procedure was repeated except that the ratio of MgOzSiO in the coating composition was increased to- 296021 as indicated:

Coating Composition B: Molar ratio The conductance of the coated surfaces of the sheets coated with Coating Composition A and Coating Composition B respectively was measured by means of the Franklin test.

Franklin test This test is widely accepted and utilized for evaluating the conductance of coated steel sheets. A detailed description is found in ASTM method A-334-52, Standard Methods of Test for Electrical and Mechanical Properties of Magnetic Materials. Briefly, the test is carried out by passing an electric current through brass contacts which cover coated areas 0.1 square inch in area. Current passing through the coating flows through the steel to a contact made directly to the steel by means of a twist drill. The resulting amperage provides a measure of the resistance encountered through the coating. Several hundred contacts are employed in obtaining readings for coating evaluation. A complete short circuit is indicated by a reading of milliamps per 0.1 square inch.

For the coatings of the present invention, Franklin test values of about 45 or less are considered acceptable. The results obtained for Coating Compositions A and B respectively are as follows:

Franklin test milliamps/ 0.1 sq. in. Coating Composition A 26 Coating Composition B 52 EXAMPLE 2 The procedure of Example 1 was repeated except that the coating composition contained the following components in the indicated ratios:

Coating Composition C: Molar ratio MgOzSiO 1480:1 B O :SiO 4.6:1 MgOzNa 2830z1 The procedure of Example 1 was repeated except that the coating composition contained the following components in the indicated ratios:

Coating Composition D: Molar ratio MgO:SiO 1480:1 B O :SiO 8.7:1 MgOzNa 2830:1

The coated annealed steel plates were subjected to the Franklin Test with the following results:

Franklin test milliamps/ 0.1 sq. in. Coating Composition C 26 Coating Composition D 58 EXAMPLE 3 The procedure of Example 1 was repeated except that the ratio of B 0 to SiO employed was 4.621 to provide a coating composition having the following components in the indicated ratios:

Coating Composition E: Molar ratio MgOzSiO 1480:1 1320 18102 MgOzNa 2800:1

composition having the following components in the indicated ratios:

Coating Composition F: Molar ratio MgOzSiO 1480:1 B203 I 2-3: 1 MgOzNa 2800:1

The coated steel plates were Observed for uniformity of coating by visual inspection. The results were as follows:

Molar ratio Uniformity of (Bros-'SiTz) coating 4.611 Excellent. 2.3:1 Barespots.

Coating Composition E Coating Composition F EXAMPLE 4 The procedure of Example 1 was repeated except that the ratio of MgO to sodium was varied while keeping the ratios of MgOzSiO and B O :SiO constant to provide coating compositions having the following components in the indicated ratios:

Steel plates were coated with Coating Compositions A, G and H respectively, and were examined visually for uniformity of coating with the following results:

Uniformity of coating Coating Composition A Good.

Coating Composition G Poor.

Coating Composition H Poor.

EXAMPLE 5 A coating composition was prepared as in Example 1, except that the molar ratio of MgOzSiO was as indicated:

Coating Composition 1: Molar ratio MgO:SiO 233021 B O 2SiO 3.5:]. MgO:Na 2800:1

The procedure of Example 1 was followed in coating this composition onto steel plates. A control consisting of MgO with no additives was also coated onto steel plates according to the same procedure. The coated steel plates were then tested for corrosion resistance by means of the Chlorine Test for Corrosion Resistance.

Chlorine test for corrosion resistance In this test strips of weighed Steel having 30 cm? of surface area rest against a thermocouple well located at the center of the hot Zone of a heated Vycor tube in an automatically controlled tube furnace. Helium flows through the tube at a linear velocity of 65 cm./min, The temperature is raised to 816 C. to simulate stress relief annealing conditions and minutes are allowed for equilibrium to be established after the temperature levels off. The gas is then suddenly switched to wet chlorine moving at cm./min. After 60 seconds, the flow is switched back to a 170 cm./min. fiow of helium. The system is then cooled to 315 C., samples removed, quenched in cold running water, scrubbed, dried and reweighed. The Weight loss due to iron and silicon chloride vaporization is an inverse measure of the corrosion resistance.

The results obtained were as follows:

A coating composition was prepared as in Example 1 except that sodium tetraborate was used instead of sodium hydroxide and the molar ratio of MgOzSiO was 943:1 to yield a composition having the following components in the indicated ratios:

Coating Composition J 2 Molar ratio MgO:SiO 943:0 B O :SiO 3.5:1 MgO:Na 280021 The procedure of Example 1 Was followed in coating this composition onto steel plates except that the coated plates were annealed for a period of 8.6 hours. The coated, annealed plates were tested for corrosion resistance according to the procedure described in Example 5.

The results obtained were as follows:

Reduction in Weight weight loss, Percent loss, compared to improvegrams control ment Coating Composition J 0.21 0. 11 34. 4 C ontrol 0. 32

EXAMPLE 7 A coating composition was prepared as in Example 1 (hereinafter coating composition K) except that sodium tetraborate was used instead of sodium hydroxide and the molar ratio of MgO:SiO was 2830:1 to yield a composition having the same ratios of components as the composition of Example 5.

The procedure of Example 1 was followed in coating this composition onto steel plates except that the coated plates were annealed for a period of 8.6 hours, The coated, annealed plates were tested for corrosion resistance according to the procedure described in Example 5.

The results obtained were as follows:

Reduction in Weight weight loss, Percent loss, compared to improvegrams control ment Coating Composition K 0. 17 0. 15 46. 9 Control 0. 32

EXAMPLE 8 A composition (hereinafter coating composition L) was prepared by fusing together magnesium metaborate, Mg(BO and SiO to prepare a frit. The frit was then comminuted and suspended in an aqueous solution containing sodium hydroxide and boric acid in such proportions to yield a composition having the same ratios of components as coating compositions I and K.

The procedure of Example 1 was followed in coating this composition onto steel plates except that the coated plates were annealed for a period of 8.6 hours. The coated, annealed plates were tested for corrosion resistance according to the procedure described in Example 5.

The results obtained were as follows:

A coating composition (hereinafter coating composition M) was prepared according to the procedure of Example 1 except that the molar ratio of MgO:SiO- was 283:1 to yield a composition having the following components in the indicated ratios:

Coating Composition M: Molar ratio MgO:SiO 283:1 1320318102 3.511 MgOzNa 280021 The procedure of Example 1 was followed in coating this composition onto steel plates except that the coated plates were annealed for a period of 8.6 hours. The coated, annealed plates were tested for corrosion resistance according to the procedure described in Example 5.

The results obtained were as follows:

Reduction in weight loss Percent compared to improvecontrol merit Weight loss, grams Coating Composition M Control EXAMPLE 10 A steel coating composition (hereinafter coating composition N) was prepared by admixing magnesium oxide, boric oxide, sodium tetraborate and silica in the following molar ratios:

Coating Composition N: Molar ratio MgOISiO 148011 B O :SiO 3.511 MgOzNa 280011 Reduction in weight loss compared to grams control ment Weight loss,

Percent improve- Coating Composition N Control While several particular embodiments of this invention are shown above, it will be understood, of course, that the invention is not to be limited thereto, since many modifications may be made, and it is contemplated, therefore, by the appended claims, to cover any such modifications as fall within the true spirit and scope of this invention.

What is claimed is:

1. A magnesium oxide composition containing a major proportion of magnesium oxide having a surface area of at least 20 square meters per gram and a minor proportion of the additives:

(I) a boron compound selected from the group consisting of boric acids, boric oxides, and magnesium borates;

(II) a sodium compound selected from the group consisting of sodium hydroxide, sodium oxide, sodium peroxide and sodium 'borate; and

(III) a silicon-containing compound selected from the group consisting of silica and alkaline earth metal silicates;

wherein the molar ratio of magnesium oxide to silica is from about 280:1 to about 2900:1, the molar ratio of boron expressed as (B to silica is from about 3:1 to about :1, and the molar ratio of magnesium oxide to sodium is from about 2000:1 to about 4000:1.

2. A composition according to claim 1 wherein the boron compound is boric acid, the sodium compound is 10 sodium hydroxide, and the silicon-containing compound is silica.

3. A composition according to claim 1 wherein the molar ratio of magnesium oxide to silica is from about 100011 to about 2000:1, the molar ratio of boron expressed as B O to silica is from about 3:1 to about 5:1, and the ratio of magnesium oxide to sodium is about 2000:1 to 400021.

4. A composition according to claim 1 wherein the molar ratio of magnesium oxide to silica is from about 1000:1 to about 2000:1, the molar ratio of boron expressed as B O' to silica is from about 3:1 to about 4:1, and the ratio of magnesium oxide to sodium is about 2000:1 to about 4000:1.

5. A composition according to claim 4 wherein the molar ratio of magnesium to sodium is about 2000Il.

6. A composition according to claim 1 wherein the aggregate mole percentage of the additives boron, silica and sodium to the total composition is up to about 2 /2 mole percent.

7. A composition according to claim 1 wherein the aggregate mole percentage of the additives boron, silica and sodium to the total composition is up to about 2 mole percent.

8. A composition according to claim 1 wherein the molar ratio of magnesium oxide to silica is about 1500: 1, the molar ratio of boric acid expressed as B 0 to silica is about 35:1, and the molar ratio of magnesium oxide to sodium is about 2800:1.

9. A composition according to claim 1 wherein the boron compound is boric acid, the sodium compound is sodium tetraborate, and the silicon-containing compound is silica.

10. A process for coating steel sheet with an electrically insulating, corrosion-resistant coating which comprises in sequence forming an. aqueous slurry of a magnesium oxide composition as defined in claim 1, coating said slurry to the surfaces of steel sheet, heating the slurry coated steel to dry said coating, and thereafter annealing said coated steel sheet.

11. A process according to claim 10 wherein the slurry has a solids content of from 5 to 20 percent by weight.

12. A process according to claim 10 wherein the silica has a particle size of up to 200 mesh (US. Standards Sieve Series).

13. A process according to claim 10 wherein the steel sheet is coiled after coating and before the annealing step.

14. A process according to claim 10 wherein the boron compound is boric acid, the silicon-containing compound is silica, and the sodium compound is sodium hydroxide.

15. A coated steel sheet having thereon an adhered coating of the composition defined in claim 1.

References Cited UNITED STATES PATENTS 1,703,630 2/1929' Meehan 14827X 2,354,123 7/1944 Horstman et al. 14831.55X 2,515,788 7/1950 Morrill 14814X 2,641,566 6/1953 Robinson 14827X 3,073,722 1/1963 Hoehn et al. 14812.1X 3,084,081 4/ 1963 Carpenter 14814 3,105,781 10/1963 Walter 148113X 3,186,867 6/1965 Forslund et al. 148113X 3,331,713 7/1967 Miller 148--113 DELBERT E. GANTZ, Primary Examiner G. E. SCHMITKONS, Assistant Examiner US. Cl. X.R.