US2618578A - Blackening stainless steel - Google Patents

Description

Patented Nova l 1952 BLACKENING STAINLESS STEEL John F. Kreml, Middletown, Ohio, assignor to Armco Steel Corporation, Middletown, Ohio, a

corporation of Ohio No Drawing. Application October 13, 1950, Serial No. 190,051

My invention relates to a method of blackening stainless steels or high alloy chromium steels by the formation on their surfaces of a black film of oxide.

It has hitherto been discovered, as set forth in Patent No. 2,394,899, issued February 12, 1946, to Irvine C. Clingan, that a tightly adherent and abrasion resistant coating of black color could be formed on the surfaces of high alloy chromium steels by a procedure which involves the clipping of the steel articles beneath the surface of a fused bath of sodium dichromate, potassium dichromate, or mixtures of the two, maintained at temperatures, roughly, between 320 C. and

500 0., and holding the articles beneath the sur- 'ment.

It is a principal object of my invention to produce black oxide coatings on the surfaces of high chromium steel articles with less equipment, more cheaply, and at a very much'higher rate of productivity for the equipment involved.

It is also an object of my invention to provide a way of forming the black oxide coatings on stainless steel articles which is available to the ordinary fabricator, without the installation of any great quantity of expensive equipment, and

13 Claims.

through the use, in partat-least,lof equipment the coatings produced is in all respects the equal of those produced in accordance with the teachings of Patent 2,394,899. They are black in color, tightly adherent, hard, tough, and uniform in texture and appearance, and highly resistant to abrasion. The actual appearance of the finished coating will vary with the initial finish of the article or product prior to the treatment. Thus,

a dull gray, unpolished piece of high chromium steel, when treated in accordance with my process, has produced upon it a dull black coating, while more highly reflective initial finishes will affect the appearance of the final coating, so that a satiny initial finish will produce a satiny black coating, and a highly polished initial finish will produce a lustrous or equally highly polished black coating.

The stainless steels or chromium alloy steels to which my invention is applicable are defined as any low carbon steel comprising 10% to 35% of chromium, with or without nickel, and with or without other alloying ingredients, such as manganese, silicon, cobalt, copper, molybdenumtungsten, vanadium, columbium, titanium, and the like, as well as those impurities ordinarily found in stainless or chromium steels. In other words, the only necessary qualification for the base steel or article is that it shall be a ferrous body containing substantially 10% to substantially 35% of chromium. Contents of other substances do not affect the formation of the black oxide coating herein described, the color and characteristics of that coating being due to its high content of the oxides of iron and chromium.

I have found that under the conditions of procedure hereinafter outlines, it is not necessary to immerse the article or piece of chromium steel in a bath of the fused dichromates and hold it there until the required oxide coating has been formed. Instead, it is readily possible to coat the surfaces of the cleaned article with dichromate and then effect the formation of the oxide coating in a separate furnace. such as an annealing furnace. This is surprising, inasmuch as it has hitherto been understood an atmos- ,,ph eric,or gaseous oxidation occurring prior to or readily possible by several procedures so to coat the surfaces of a clean piece or article of chromium steel with a dichromate, that atmospheric oxidation will be prevented during the heatingup period of a subsequent treatment of the coated articles in a furnace, while the coating of dichromate will remain in place during the heat treatment and will be sufficiently continuous and impe'rforate to prevent atmospheric oxidation, in

spite of the fact that the dichromate or dichromates are raised above their fusion point.

As in the practice of the process of Patent 2,394,899, the articles vor pieces must first be cleaned. so as to eliminate substantially all scale, oxide, grease. dirt and the like. Mechanical cleaning methods may be employed such as sand blastins. grinding and the like, with or without pickling. If a pickling is employed. any pickle suitable for use with high chromium steels may be adopted. In pickling stainless steel products, a quick dipping in an aqueous solution of nitric acid and 1% hydrofluoric acid is -.usually sufficient. This is followed by a rinse in clean water.

In addition to pickling, or as a substitute therefor, where a highly polished surface is desired, this may be secured by buiilng or other mechanical methods; but I prefer to use any one of those methods of electrolytically polishing stainless or chromium steels, such as the .process of Ostroisky, Patent 2,335,354,v Feild,

Patent Re. 23,068, or Patent 2,424,674ln the name of Harold I. White. Electrolytic cleaning, as distinct from electrolytic polishing, may be employed if desired. Any of these processes, after the piece has been suitably rinsed, will tend to leave its surfaces adequately clean. The cleaning procedure does not, as to its nature, form a limitation upon the present invention.

One of the ways of securing a coating of dichromate on the surfaces of a stainless steel material or article suitable for my purpose is by dipping the article in a bath of the molten dichromate. The bath may consist of sodium dichromate, potassium dichromate. or mixtures of the two. All that is necessary is to immerse the piece or article in the molten bath for a sumcient length of time to permit the adherence of a coating of the dichromate. This dipping may be done very rapidly in a bath of the salt or salts maintained at any temperature above the melting point of the bath, and below the points; which heat-decomposition is encountered. In general the temperature of the bath will be over about 320 C., and while the decomposition temperature will vary with the ratio of sodium dichromate to potassium dichromate, if both are used, (the decomposition temperature of potassium dichromate being the higher, and tending to raise the decomposition temperature of the bath), ordinarily the temperature of the bath will be less than about 500 C. Temperatures even above decomposition temperature may be tolerated; but are preferably avoided in order to avoid changes in the bath. Since the black oxide coatings are, in my process, not formed while the article or piece is submerged in the bath of fused salt, there is no advantage in using the highest possible temperatures in order to speed up the chemical attack.

I have found that if an article is dipped in a bath of sodium or potassium dichromate or mixa liquid at a temperature above the melting.

. perature around 455 C.

point of the dichromate or dichromates, or by swabbing the surface of the piece or article with the molten salt. When swabbing. spraying or the like is practiced, it becomes possible to apply the material selectively, as by coating only one surface of the article or piece. In any event, the productivity of any piece of apparatus in which a molten dichromate bath is maintained is very greatly increased since the time cycle has been very greatly shortened, as will now be evident. The specific thickness of the coating is not a limitation on my invention. Coatings of fused salt may range from that minimum mentioned above to any desired thickness, the only disadvantage of thicker coatings lying in the loss of the salt or salts themselves through the use of unnecessary quantities thereof. -In actual practice I have found that an excess of coating will tend to drain away from the surfaces of the piece or article, without interrupting the continuity of the remaining minimum coating, under the conditions of operation of the subsequent furnace treatment.

when the stainless or chromium steel piece or .article has been coated with the required film, it is then placed in an oven operated at a temperature roughly between 320 C. and 500 C. but preferably at an intermediate tem- The length of time the piece remains in the furnace should be sufficient to permit the article to come up to the temperature of the furnace or oven, and the desired blackening action to take place, but an excess of time has no effect. Satisfactory coatings are obtained, for example, by holding the 7 .minutes, depending on the temperature used and the section of the article being treated. Heavier sections require a longer time.

The use of an ordinary furnace or oven for the longer part of the process permits the use of a simpler routing with only a short immersion time in a fused salt bath or with swabbing or spraying of the fused salt, as compared to carrying out the entire process by immersion in a salt pot. Where immersion is relied upon for the formation of the coating, the piece or article must remain in the pot, as indicated above, for periods of time ranging generally from 2 to 30 minutes; and it will be clear that the productive capacity of any given pot apparatus is severely limited. On the other hand, heating or annealing furnaces are standard equipment, particularly in the plants of those who fabricate articles from stainless or chromium steels and are not normally used to capacity. In my process use is made of such furnaces and, therefore, small manufacturers or fabricators can practice my process without the installation of elaborate one-use salt pots large enough to permit the immersion of articles for the entire period of the chemical interaction.

The dipping time, if dipping is practiced in my process, is only a fraction of that required for the chemical interaction. My process thus lends itself to continuous production line methods. The nature of the articles treated does not form a limitation, and they may range from large sheetlike bodies to small parts such as screws, bolts,

ferrules, bezels and the like, which small parts would normally be dipped in suitable baskets. If continuously blackened strip or wire made from stainless or chromium steels is required, it may be formed in my process by continuously passing the strand through a relatively small bath of a d fused salt and then into and through a continuous furnace in which the chemical reaction will take place.

When the chemical reaction is complete, any residue of salt may be washed from the surfaces of the article with conventional equipment. The black coatings formed in my process are suitable not only for decorative uses, but there are many utilitarian uses in which they have importance. By way of a single example, the metal bodies of television tubes require to be blackened, and my process is excellent for this purpose. The tube bodies have a thin wall section making possible a very short time of immersion in the molten salt bath to bring the body up to bath temperature to obtain, as set forth above, a suitable thin film. of the fused salt or salts with minimum drag-out. The greater part of the time required for the chemical reaction occurs in the subsequent furnace which may be any suitable type of heat treating furnace. Where dipping is practiced, I prefer to accomplish this at temperatures around 400 C. and to employ the aforesaid temperature around 455 C. in the subsequent furnace or oven. The atmosphere in the furnace does not require control and can even be reducing, although this involves unnecessary expense. A neutral or oxidizing atmosphere is ordinarily preferred. The atmosphere may be an atmosphere of products of combustion in a fuel-fired furnace, or where other heating means are used, such as radiant tubes or electric heating elements, a furnace atmosphere of air is entirely satisfactory. The temperature for furnace heating may be varied over a wide range, and it is even possible to tolerate a temperature above the decomposition temperature of the fused salts since the chemical reaction occurs very rapidly and ordinarily there is an excess of the dichromate or dichromates acting as oxidizing agents over and above that required for the formation of the desired black coatings.

I have further found that the salt or salts may be applied to the cleaned metal articles or pieces otherwise than in a fused condition. It is readily possible to apply them in water solution at any temperature below the boiling point. The articles may be dipped into a tank containing such a water solution, or they may be treated by swabbing, spraying and the like. In the use of water solutions, the problem becomes more complex in that the temperature and concentration of the dichromate or dichromates in solution as well as the conditions of coating should be controlled to obtain large spangled crystals on the "surfaces of the metal pieces or articles.

. *In- 'the"formationofsatisfactory.black coatings by my method, the cleaned chromium steel pieces should be protected from atmospheric oxidation, since this is productive of a heat tint which may give an undesirable color and is likely to impair the quality of the coating. A film of dichromate solution which dries on the metal pieces in the form of tiny separate crystals will not protect the work from heat tintin during the heating-up cycle in the furnace or oven and prior to the complete melting of the salt or salts. As a, consequence, I prefer to employ aqueous solutions which are to coat the pieces under such circumstances that a large or Spangled crystal formation is obtained upon drying. One way of producing such large spangles is to make up an aqueous solution of the salt ranging from to nearly 100% saturated at room temperature and to apply it to the article as by dipping, swabbing or spraying. I have found that such a coating is without departing from the spirit of it.

sumciently impervious for my purpose and that it will remain so during the heating-up cycle in the oven or furnace. A preliminary heating of the pieces to a temperature approaching, equal to. or slightly above the boiling point of the solution is helpful'in the obtaining of imperforate coatings. Where the solution is sprayedon, using a solution saturated at elevated temperatures, so that the tendency is to form the minute. discrete crystals referred to, it is within the scope of my invention to coat it a plurality of times in order to obtain an imperforate layer of the dried salt or salts. Furthermore, whenever an aqueous solution is applied to the articles or pieces by spraying, I prefer to employ two or more coats as a precautionary measure to insure complete coverage.

While in a clipping procedure in fused salt some chemical reaction may be begun in the bath, there is no detectable chemical reaction or blackening which takes place when the articles or pieces are coated with an aqueous solution by dipping or spraying at any temperature up to their boiling point and are then dried at normal temperatures or by means of heated air. Under these circumstances the entire chemical reaction will take place in the subsequent furnace or oven.

The use of water solutions of the dichromate ordichromates which are not so concentrated as to become supersaturated during, application, the use of elevated solution temperatures, and the warming of the pieces, all contribute to the formation of a spangled crystal condition which I have found to be inhibitive of atmospheric oxidation. It is within the scope of my invention to add to water solutions of the dichromate or dichromates surface active agents to increase the wetting and assist in the formation of air impervious crystalline coatings.

Modifications may be made in my invention Having thus described my invention in certain exemplary embodiments, what I claim as new and desire to secure by Letters Patent is:

1. A process of producing a black oxide coating on chromium steel articles which comprises coating the cleaned articles with an imperforate layer of salt chosen from a class consisting of sodium dichromate and potassium dichromate and mixtures thereof, passing the articles into a furnace maintained at a temperature between substantially 320 C and 500 C. for a heat treatment having a duration of substantially 2 to substantially 30 minutes, and thereafter washing the articles to remove from the surfaces thereof any residue of unreacted substance.

2. The process claimedimclaim lin which the furnace atmosphere is oxidizing.

3. The process claimed in claim 1 in which the coating of salt is applied to the steel articles by dipping them into a bath of fused salt and withdrawing them therefrom.

4. The process-claimed in claim 1 in which the coating of salt is applied to the steel articles by dipping them into a bath of fused salt and withdrawing them therefrom, and in which the articles are left in the 'bath for such length of time as to cause them to reach substantially the temperature of the bath, whereupon they are withdrawn therefrom and drained.

5. The process claimed in claim 1 in which the coating of salt is applied to the steel articles by dipping them into a bath offused salt and withdrawing them therefrom, and in which the articles are left in the bath for such length of time 7 as to cause them to reach substantially the temperature of athe bath. whereupon they are withdrawn therefrom and drained, and in which the said furnace has an oxidizing atmosphere.

6. The process claimed in claim 1 wherein the fused salt is applied to at least one surface of the cleaned article by swabbing.

'7. The process claimed in claim 1 in which the fused salt is applied to the surface of the cleaned article by spraying.

8. The process claimed in claim 1 in which the salt is applied to the surface of the cleaned article in water solution, a film of the water solution being subsequently dried on the surface of the article.

9. The process claimed in claim 8 wherein the solution is less than saturated at and is applied at an elevated temperature.

10. The process claimed in claim 8 wherein the solution is 5% to 100% saturated at the temperature of application, and is applied to the surface of the cleaned article by spraying.

11. The process claimed in claim 8 wherein the dried coating of salt on the surface of the article is crystalline and is characterized by a spangled crystalline condition.

12. A process of producing a black oxide coating on the surface of a chromium steel article which comprises dipping the cleaned article in a fused bath of salt at a temperature of substantially 400 C., said salt being chosen from a class consisting of sodium dichromate, potassium dichromate and mixtures thereof, maintaining the said article in said bath until it reaches substantially bath temperature, withdrawing and draining it, passing it into a furnace wherein it is maintained at a temperature of substantially 455 C. for a time between substantially 2 to 30 minutes, and thereafter washing the article to remove from the surface thereof any residue of unreacted substance.

13. A process of producing a black oxide coating on the surface of a chromium steel article which comprises dipping the cleaned article in a fused bath of salt at a temperature of substantially 400 (2., said salt being chosen from a class consisting of sodium dichromate, potassium dichromate and mixtures thereof, maintaining the said article in said bath until it reaches substantially bath temperature, withdrawing and draining it, and passing it into a furnace wherein it is maintained at a temperature of substantially 455 C. for a time between substantially 2 to 30 minutes, thereafter withdrawing the said article from the said furnace, cooling it and washing from its surface any residue of unreacted substance.

JOHN F. KREML.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Clingan Jan. 9, 1951

Claims (1)

1. A PROCESS OF PRODUCING A BLACK OXIDE COATING ON CHROMIUM STEEL ARTICLES WHICH COMPRISES COATING THE CLEANED ARTICLES WITHAN IMPERFORATE LAYER OF SALT CHOSEN FROM A CLASS CONSISTING OF SODIUM DICHROMATE AND POTASSIUM DICHROMATE AND MIXTURES THEREOF, PASSING THE ARTICLES INTO A FURNACE MAINTAINED AT A TEMPERATURE BETWEEN SUBSTANTIALLY 320* C AND 500* C. FOR A HEAT TREATMENT HAVING A DURATION OF SUBSTANTIALLY 2 TO SUBSTANTIALLY 30 MINUTES, AND THEREAFTER WASHING THE ARTICLES TO REMOVE FROM THE SURFACES THEREOF ANY RESIDUE OF UNREACTED SUBSTANCE.