CH461920A - Process for obtaining a dull or mat finish on a ferrous metal containing carbon - Google Patents

Description

  

  Method of Obtaining a Dull or Matte Finish on a Ferrous Metal Containing Carbon The present invention relates to an improved method of treating metal surfaces and, more particularly, to a method of obtaining a dull or mat finish on metal surfaces. ferrous containing carbon.



  When preparing metallic surfaces, and particularly ferrous metal surfaces containing carbon, to receive a coating, such as an electric coating, a protective coating or a paint primer coating, such as a phosphate coating, and / or paint coating, etc., it is generally desirable that the metal surface has a dull or mat finish. When coatings of this type are applied over a dull or matte finish, there is generally much better adhesion between the coating and the surface than when the surface has a more glossy or glossy finish.

   Normally, this desirable dull or mat finish is achieved by subjecting the ferrous metal surface to the action of an acid pickling solution such as an aqueous solution of sulfuric acid or hydrochloric acid.



  In some cases, however, it has been found that the ferrous metal surfaces to be treated have a metallic luster which is virtually unaffected by conventional treatment with acid pickling solutions. In these cases, treatment with an acid pickling solution does not produce a dull or mat finish on the surface of the ferrous metal, but at least a semi-gloss surface remains after treatment. Although we do not know what the nature of this shiny surface on iron metal is, nor do we know in general why it is resistant to acid pickling solutions, we have found that, when it remains on the ferrous metal, one may encounter difficulties in obtaining a high quality adherent coating on that surface, such as those indicated above.

      In some cases, it has been found that this flashing surface on the ferrous metal can be physically removed, for example by grinding or sandblasting, but, in general, these procedures are not desirable. Not only is a grinding or sandblasting operation expensive and time consuming, especially when dealing with irregular surfaces, but, furthermore, if the dimensions of the part are changed by such operations, it is likely that the The use of these techniques will be out of the question. Consequently; Heretofore, there is no perfectly satisfactory procedure for easily and economically treating a ferrous metal having a shiny surface, in order to obtain a dull or mat finish on the metal.



  Accordingly, it is an object of the present invention to provide an economical and simple method of treating a ferrous metal having a shiny surface, so as to produce a matte finish on the metal, which process does not cause substantial modification in the materials. dimensions of the treated metal.



  In order to achieve the aforementioned objects, the present invention relates to a process for obtaining a dull or mat finish on a ferrous metal containing carbon and having a shiny surface which is normally practically unaffected by an acidic solution of carbon. pickling, a process whereby the metal surface is brought into contact with an acid pickling solution, the solution is kept in contact with the surface for a time of at least five minutes, but insufficient to form a carbonaceous deposit on the surface , the surface is contacted with an alkaline solution of perman ganate and then the surface is contacted with an acid pickling solution for a period of time sufficient to form a matte finish on the surface.

   In carrying out this process, the combined use of the acidic pickling solution followed by the alkaline permanganate solution attacks, in some way, the shiny surface of the ferrous metal, thereby making the solution acidic. effective subsequent stripping to form a matte finish on the surface. Neither acid pickling nor the permanganate solution alone was found to give these results.



  Although it is preferable to effect the contacting of the ferrous metal and the acid pickling product by immersing the ferrous metal surface in the acid pickling solution, it will be appreciated that the pickling solution can be supplied to 'other ways in contact with the metal surface, for example by spraying, draining, etc. However, it has in many cases been found that the most economical use of the acid pickling solution is achieved when the metal surface is immersed therein and, for this reason, reference is made primarily to the following. below when the ferrous metal comes into contact with the acid decay solution by immersion.



  Generally, contact times of about five to forty-five minutes are typical, contact times of about eight to twenty minutes being preferred. Although in some cases longer contact times may be used, it is important that the duration of contact between the pickling solution and the surface of the ferrous metal containing carbon is not sufficient for this to occur. a deposit because good on the surface of the metal.

   Consequently, when choosing the contact time, this factor must be taken into account so that the contact times that can be used between the acid pickling solution and the ferrous metal are between five minutes and a time which would cause formation. a substantial amount of carbonaceous deposit on the surface of the ferrous metal.



  A variety of acidic aqueous pickling solutions can be used. These can be composed from a variety of acids including organic acids and aci minerals such as sulfuric acid, hydrochloric acid, phosphoric acid, ete. For example, the pickling solutions are aqueous solutions of mineral acids and are preferably aqueous solutions of sulfuric acid or hydrochloric acid. While various concentrations of these acidic solutions can be used, concentrations of about 5 to 25% / a being typical, acid concentrations of about 10 to 20% based on the weight of the solution are preferred.



  After contacting with the acidic aqueous pickling solution for the desired time, - the metal surface is then brought into contact with an alkaline permanganate solution. Again, it is preferable to effect the contacting by dipping the iron metal surface in the permanganate solution, although other methods of contacting can also be used. Alkaline permanganate solution is an aqueous alkaline solution containing an alkali metal permanganate.

   By alkali metal permanganate is meant to refer to lithium, sodium, potassium, cesium and rubidium permanganates. Of these, potassium permanganate is preferred and, therefore, primarily this substance will be referred to below. The amount of potassium permanganate in this solution is at least that amount which provides the desired activation of the surface to cause the acidic pickling solution subsequently applied to be effective in removing the shiny finish of the metal.

   Typically, the potassium permanganate is present in the treatment solution in an amount of between about 5 and 50 g / liter and, preferably, in an amount of about 15 to 35 g / liter. It is obvious that in certain cases the treatment solution may contain potassium permanganate in amounts greater or less than those indicated, provided that the amounts used are sufficient to achieve the aforementioned desired activation. of the metal surface. Besides the alkali metal permanganate, the metal treatment solution according to the present invention may also contain an alkali metal hydroxide.

   Although various alkali metal hydroxides can be used, such as, for example, lithium, sodium, potassium, cesium or rubidium hydroxides, it has been found to be generally preferable to use. liser sodium hydroxide in the treatment solution according to the present invention. For example, sodium hydroxide is present in an amount of between about 10 and 200 g / liter, with an amount of about 20 to 150 g / liter being preferable.

   It is believed that the alkalinity added to the treatment solution by the addition of sodium hydroxide to some extent increases the efficiency of the permanganate in activating the surface of the ferrous metal, so as to make the solution acidic. Decaf subsequently applied, effective in producing a matte finish on the surface. Accordingly, in some cases, larger or smaller amounts of the alkali metal hydroxide may be used in the treatment solution, provided that whatever amount is used is at least sufficient to achieve this desired enhancement of the effectiveness of the permanganate solution.



  The alkaline permanganate solution is kept in contact with the ferrous metal surface for a period of time which is at least five minutes to achieve the desired activation of the iron metal surface so that the acidic pickling solution is subsequently obtained. properly applied is effective in removing the glossy finish from the surface. For example. the contact times used are between about two and twenty minutes, contact times of about five to fifteen minutes being preferable. As with the acid pickling solution, both longer and shorter contact times can be used, in some cases, provided that the required activation of the ferrous surface is obtained.

      After the desired contact of the iron surface with the potassium permanganate solution, the surface is again contacted with an acid pickling solution. The pickling solutions which can be used are the aqueous acid solutions as described above, and the ferrous surface can be contacted with them by immersion, or other method of contacting as described above. -above.

   In general, the acid pickling solution with which the surface is brought into contact after treatment with the permanganate solution is of the same type as the acid pickling solution with which the iron surfaces are brought into contact prior to the treatment. by the alkaline permanganate solution.

   It will be appreciated, however, that if desired, a different acid pickling solution can be used in the treatments preceding and following the per alkali manganate treatment. After the per-manganate treatment step, the ferrous metal surfaces are maintained in the acid pickling solution for a period of at least five minutes to achieve a dull or mat finish on the ferrous metal. Here again, it is important that the contact times are not sufficient to cause a deposit of carbonaceous soot on the surface of the ferrous metal. As examples of the contact times used, mention will be made of those reaching up to approximately five minutes, times ranging between several seconds and approximately three minutes being typical.



  After the second stage of acid pickling, the ferrous metal surfaces which have been treated are ready for the application of various coatings, for example electric coatings, phos phate coatings, paint, etc. If desired, the surfaces can be rinsed with water after they have been removed from the second acidic pickling solution, so as to remove any residual acid which may remain on the metal surface. Similarly, water rinses can be carried out between the other treatment stages of the process, i.e. between the first acid pickling solution and the permanganate solution, and between the permanganate solution and the second acidic pickling solution.



  When preparing the alkaline permanganate solutions for use according to the present invention, a dry composition is prepared by mixing potassium permanganate and sodium hydroxide in amounts sufficient to achieve the desired concentration of these constituents in the aqueous solution. . This dry composition is then mixed with water, in order to obtain the aqueous treatment solution. For example, such a dry composition may contain from 40 to 95 parts by weight approximately of sodium hydroxide and from 5 to 60 parts by weight approximately of potassium permanganate. Amounts of sodium hydroxide in the range of about 60 to 90 parts, by weight, and amounts of potassium per manganate in the range of 10 to 40 parts by weight, are preferable.



  When formulating such a dry composition, it may be desirable to include therein an alkali metal carbonate, such as sodium carbonate, for example. In particular, when the sodium carbonate is included in the dry mixture, it is present in an amount of between about 5 and 50 parts, by weight, with amounts of about 10 to 40 parts, by weight, being preferable. A particularly preferred composition of this type, to be used for the preparation of the aqueous alkaline permanganate treatment solution according to the present invention, contains about 60 parts by weight of sodium hydroxide, about 20 to 25 parts by weight of sodium permanganate and about 15 to 20 parts by weight of sodium carbonate.

    



  As noted above, such a dry mixture is mixed with water in amounts sufficient to obtain an aqueous treatment solution containing the alkali metal hydroxide and the alkali metal permanganate in the amounts which have been indicated. When the dry mixture contains an alkali metal carbonate, this component is present in the aqueous treatment solution in an amount of about 5 to 50 g / liter and, preferably, in an amount of about 15 to 35 g / liter.

   A preferred particular aqueous treatment solution contains about 120 g / liter of sodium hydroxide and about 30 g / liter of sodium permanganate and about 30 g / liter of sodium carbonate.



  When carrying out the process according to the present invention, a ferrous metal having a shiny surface which is normally substantially unaffected by an acidic pickling solution is contacted, preferably by immersion, with an aqueous acidic solution, by example an aqueous acidic solution of sulfuric or hydrochloric acid. This acid stripping solution is kept in contact with the surface of the ferrous metal for about fifteen minutes. The metal surface is then removed from the pickling acid and, preferably, it is rinsed with water in order to remove any traces of acid solution remaining on its surface.

   Next, the ferrous metal surface is brought into contact, preferably by immersion, with an aqueous alkaline per manganate solution, preferably containing about 120 g / liter of sodium hydroxide, 30 g / liter of potassium permanganate and 20 g / l. g / liter of sodium carbonate. It is desirable that this solution be at a temperature above room temperature, i.e. above 200 ° C., temperatures of about 25 to 1000 C being typical, temperatures of about 50 to 851> C being. preferable.

   It is preferable to keep the surface of the ferrous metal in contact with the permanganate solution for about ten minutes. Then, it is desirable to rinse the surface of the ferrous metal with water, so as to remove any traces of alkaline permanganate solution remaining on the surface, and then again contacted with the acidic aqueous pickling solution. It is preferable that this solution be the same as that previously used and the surface is maintained therein for a sufficient period of time to produce a matte finish on the ferrous metal.

   For this purpose, contact times of about two minutes have often been found to be suitable. When the matte finish has been obtained on the surface of the ferrous metal, the metal is removed from the acid solution and, desirably, another water rinse is performed to remove any acid remaining on the surface. The surfaces thus treated are then ready for the application of any subsequent coating, as indicated above.



  The following examples are given by way of illustration of the invention. In these examples, unless otherwise indicated, temperatures are in degrees centigrade and parts are by weight.



  <I> Example 1 </I> Pieces of steel are immersed in an aqueous solution of sulfuric acid containing about 15% by weight of H 3 SOI for about fifteen minutes. The sulfuric acid solution is at a temperature of about 75. These parts, before being immersed in the sulfuric acid solution, present a brilliant finish on the surface. After removing the sulfuric acid solution and rinsing with water to remove any acid remaining on the surface of the parts, it is noted that the glossy finish of the surface is practically unchanged by contact with the acid.

   These parts are then immersed for ten minutes in an aqueous solution containing approximately 108 g / liter of sodium hydroxide, approximately 36 g / liter of potassium perm ganate and approximately 36 g / liter of sodium carbonate. This aqueous solution is at a temperature of about 80 and is prepared by dissolving in water a dry composition containing about 60 parts by weight of sodium hydroxide and about 20 parts by weight of permanganate, as well as 20 parts by weight. weight, approximately, of sodium carbonate, in an amount to obtain a concentration of the total dry mixture of about 180 - / liter.

   After ten minutes, the parts were removed from the permanganate solution and the high gloss finish on the metal surface was observed to be virtually unchanged. The parts are then rinsed with water, and they are immersed a second time in the acid solution, for two minutes. At the end of this time, the parts are removed from the acid solution and they are seen to have a dull, matte finish on their surface, the shiny finish that was previously on the surface having been completely removed. When these parts are treated with a conventional zinc phosphate coating solution, an excellent adherent protective phosphate coating is obtained on the parts.

      <I> Example 2 </I> The procedure of Example 1 is repeated, except that the alkaline aqueous solution of per manganate contains only 30 - / liter of potassium permanganate and 20 - / liter of sodium hydroxide. This solution is prepared by dissolving in water a dry composition containing about 60 parts by weight of potassium permanganate and 40 parts by weight of sodium hydroxide. As in the previous example, after treatment with the second aqueous acid solution, a dull, mat finish is obtained on the surface of the parts.

      <I> Example 3 </I> The procedure of Example 1 is repeated, except that the aqueous solution of permanganate contains only 15 - / liter of potassium permanganate and 20 - / liter of potassium hydroxide. sodium. This solution is prepared by dissolving in water a dry composition containing about 57 parts by weight of sodium hydroxide and 43 parts by weight of potassium permanganate. As in the previous examples, the glossy finish on the surface of the steel pieces is completely removed in the second acid pickling solution and a dull, matte finish is obtained on these pieces.

      <I> Example 4 </I> For comparison, pieces of steel, of the same type as those used in Example 1, are immersed in an acid pickling solution, as described in Example 1, for a period of forty-five minutes. At the end of this time, the parts are removed and a thick deposit of carbonaceous soot is found to have formed on the surface of the parts. When this soot deposit is removed, the high gloss finish on the surface is found to be virtually unaffected by the acid treatment. When these parts are treated with a conventional zinc phosphate coating solution, the resulting coating is of poor quality, exhibiting poor adhesion and being generally unsatisfactory.

      <I> Example S </I> For further comparison, we repeat the operating mode of the previous example, with the exception that we use, instead of acid pickling solution, only an alkaline solution of permanganate as described in Example 1. After leaving this permanganate solution, the high-gloss finish on the parts was found to be virtually unaffected by the solution. A portion of these parts is then brought into contact with an acid pickling solution, as in Example 1, and it is maintained in this solution for a period of approximately fifteen minutes, after which time traces of a carbonaceous soot begins to form on the surface of the metal.

   When these parts are removed from the pickling solution, the high-gloss finish on the metal surface is found to be virtually unaffected by the pickling solution. When both sets of parts are treated with a conventional acidic zinc phosphate coating solution, the coatings produced are of poor quality, exhibit poor adhesion and are generally unacceptable.



  The procedure of Example 1 is repeated using a hydrochloric acid pickling solution and a permanganate treatment solution containing sodium permanganate, potassium hydroxide and potassium carbonate, and obtains comparable results.

 

Claims (1)

CLAIM Process for obtaining a dull or mat finish on a ferrous metal containing carbon and exhibiting a shiny surface which is normally practically unaffected by an acid pickling solution, characterized in that the surface of said metal is applied. metal in contact with an acid pickling solution, said solution is maintained in contact with the surface for a period of at least five minutes and insufficient to form a carbonaceous deposit on the surface, the surface is brought into contact with a alkaline permanganate solution, then with an acidic stripping solution for a period of time sufficient to form a matte finish on the surface. SUB-CLAIMS 1. A method according to claim, wherein the alkaline permanganate solution is an aqueous solution containing an alkali metal permanganate and an alkali metal hydroxide. 2. A method according to sub-claim 1, wherein said alkali metal permanganate is potassium permanganate and said alkali metal hydroxide is sodium hydroxide, potassium permanganate being present in an amount between 5 and approximately 50 - / liter and sodium hydroxide being present in an amount of between 10 and 200 - / liter approximately. 3. A process as claimed in sub-claim 2 wherein the potassium permanganate is present in the solution in an amount of about <I> 15 to 35 </I> - / liter and the sodium hydroxide is present in the solution in a quantity of 20 to 150 - / liter approximately. 4. A method according to sub-claim 2, wherein the solution also contains an alkali metal carbonate in an amount of about 5 to 50 - / liter. 5. A method according to sub-claim 3, wherein the solution also contains sodium carbonate in an amount of about 15 to 35 - / liter. 6. A process according to claim, wherein the metal surface is contacted with an acid pickling solution, the solution is kept in contact with the surface for about five to forty-five minutes, the surface is contacted with a alkaline permanganate solution for a period of about two to twenty minutes, said alkaline permanganate solution containing an alkaline permanganate in an amount of about 5 to 50 g / liter and an alkali metal hydroxide in an amount of 10 to 200 g / liter approximately, and then the surface is again contacted with an acid pickling solution for a sufficient period of time to form a mat finish on the metal surface. 7. A method according to sub-claim 6, wherein the ferrous metal surface is initially contacted with the acid pickling solution for a period of about eight to twenty minutes and then contacted with the alkaline solution of Perman ganate for about five to fifteen minutes.