US2257890A

US2257890A - Lubricating composition

Info

Publication number: US2257890A
Application number: US692030A
Authority: US
Inventors: Reginald G Sloane
Original assignee: Standard Oil Development Co
Current assignee: Standard Oil Development Co
Priority date: 1933-10-03
Filing date: 1933-10-03
Publication date: 1941-10-07
Anticipated expiration: 1958-10-07
Also published as: DE748242C; GB425569A; FR778545A

Description

Patented Oct. r, 1941 UNHED STATES LUBRICATING COWOSITION Reginald G. Sloane, Elizabeth, N. 3., assignor to Standard Oil Development Company, a cornotation of Delaware No Drawing. Application October 3, 1933, Serial No. 692,030

5013M The present invention relates to improved 1 lubricating oils and more specifically-to oils of high stability both toward oxidation and sludge formation as in .a continuation-in-part of the previous application Ser. No. 408,421 filed No vember 19, 1929, now Patent No.- 1,966,050 issued July 10, 1934. The invention will be fully understood from the following description.

It has been observedthat after lubricating oils have received a high degree of refinement they are often more unstable particularly toward oxidation than the impure or crude cutsirom which they were obtained. Thereason for this is thought to be that the refining process removes substances which act as inhibitors of oxidation. Furthermore, inhibitors of this type are known suchas the cresolsand naphtholswhich when added in relatively smau'amounts to lubricating oils showing a high oxidation rate cause a considerable reduction.

The present invention relates to a new class. of inhibiting substances which are considerably more powerful than thosepreviously known.

This new class of inhibitors comprises in its broadest sense aromatic sulfur compounds in which the sulfur atom is attached directly to a" carbon atom. These suiistances make up a rather large class and the-ones of special commercial value are'those boiling above 150 C. or preferablyevemhigher, say. above 180 or 200 C., and

able but the other groups mentioned, while not particularly desired, do not destroy the effect of the mercaptan or disulfide groups. In the same manner carboxyl, aldehyde and keto groups may be present. It will be understood that the compounds containing only carbon, hydrogen and sulfur are preferred, particularly disulfides and mercaptans.

While the above description has been limited entirely to sulfur compounds, it should be understood that in each case selenium or tellurium may be substituted for the sulfur atom, but for reasons of economythe sulfur derivatives are preferred. It is also usually the case that the sulfur compounds are more active.

The oils in which the present inhibitors are to be used are more especially those which are substantially parafilnic in type, for example,

has a maximum absorption rate in excess of which for this reason will notbe lost during the use of the lubricant at such temperatures as are likely to beencountered in the lubrication of automotive engines. or the like. Aromatic disuliides. and mercaptans may be used such as phenyl, cresyl or higher al blated disulfides, mercaptans and the corresponding naphthyl or anthryl, phenanthryl derivatives or their alkylated products and the relative pomtions of the sulfur and alkyl groups in the rings are of only minor significance, all being of good inhibiting power. ,More than one-jsulfur atom may be attached to a single ring if desired, as in the di or tri thio-phenols, cresols and naphthols.

All of the substances mentioned .above consist only of the elements carbon, hydrogen and sulfur or, in other words, they are sulfurized hydrocarbons, and while these are generally preferred other elements may be present in the molecule without disadvantage, for example, oxygen or nitrogen and similar elements. As examples of such materials can be mentioned aromatic disulfides and mercaptans containing hydroxy,

, nitro, amino, azo and hydrazo groups. The presence of the hydrow group is particularly desir- 55 about 50 cc. of oxy en per fifteen minute interval per 10 cc. of sample when agitated with oxygen at a temperature of about 200 -C. The rates of oxidation for well refined oils of the type mentioned above may beffar in excess of the figure mentioned, for example, they may be up to 100 or 180 cc. absorption or even up to 300 cc.

in very pure parafilnic oils.

Other classes of oils in which the improved inhibitors are of great advantage are the highly refined white oils produced by the actionof fuming or concentrated sulfuric acid. and also destructively hydrogenated oils or oils prepared by strong hydrogenation at low temperatures.

While the inhibitors mentioned above are of the greatest advantage with oils listed la the previous paragraphs because of their high oxidation rate, they have also been found to be so powerful as to likewise show a considerable reduction in the oxygen absorption rate of lower grade oils of more or less naphthenic or ,asphaltic types such as the Coastal or California oils which are characterized by a viscosity index below 50- or even 30 and by oxidation rates of the order of 30 cc. in the units mentioned above. It may well be that the action of the present inhibitors is difierent from the ordinary naphtholic or cresolic inhibitors, since these latter show substantially no effect whatever on the naphthenic types of oils. on the other hand, the present inhibitors reduce the oxidation rate to a considerable degree, for example, by as much as one-half. It should be noted, however, as stated above, that the inhibitors are not of greatest value in connection with these oils since their oxidation rates are already low.

The amount of the various inhibitors which may be used depends upon the oil to which it is to be added, the particular inhibitor, and also to the conditions which are likely to be encountered. In general the substances are considerably more powerful than cresols or naphthols and for this reason may be used in smaller quantities. It may be said that if the oil is designed to stand higher temperatures, the amount of the inhibitors should be increased. The new inhibitors are effective when used in amounts as little as .01% in the case of very highly refined oil such as white oil or other less highly refined oils when used in the lower temperature range, for example, under 150 C., but ordinarily more is desired, for example .05 or .10%, or in some cases even more. Of the various compounds the disulfides are preferable to mercaptans because they have a less objectionable odor.

As illustrations of the materials used and their action in various lubricating oils, the following examples are given:

Example I A well refined lubricating oil having a viscosity of approximately 145 seconds Saybolt at 100 F. is blown with a steady volume of air, 10 cu. ft. per hr. at 300 F. (149 0.). The sample was 300 gr. At intervals the free acid was determined by titration with alkali. The following table gives the rate of acid formation with time, in respect to the Blank sample containingno inhibitors, and the same oil containing specific inhibitors.

Acidity-MgKOH per qt. of oil Tlme 11mm 1 4% tbio 3% thio 3% di- Blank beta beta (figienyl naphthol nsphthol ulilde Oxygen absorption .1% of a mixture of the last two .l% dimereapto diphenyl .1% alpha naphthol disuliide Blank thio WWWN HHD-IN Owen l-nlbmlm The present invention is not to be limited by any theory of the reaction of oxidation or inhibition thereof, nor to any particular inhibitors or oils containing them, but only to the following claims in which it is desired to claim all novelty inherent in the invention.

I claim:

1. The combination, with a highly refined viscous mineral oil, of a sufficient quantity of a disulfide of an aromatic compound containing only the elements carbon, hydrogen and sulfur, to reduce substantially the tendency of the oil to form acidic material through oxidation.

2. The combination, with a highly refined viscous mineral oil, of a suflicient quantity of diphenyl disulfide to reduce substantially the tendency of the oil to form acidic material through oxidation.

3. A composition of matter comprising a petroleum lubricating oil characterized by a high initial rate of oxidation containing dissolved therein, in an amount suflicient to reduce substantially the tendency of the oil to form acidic material through oxidation, an oxidation inhibitor selected from the class consisting of alpha and beta naphthyl mercaptans.

4. The composition of matter according to claim 3, in which the inhibitor is beta naphthyl mercaptan.

5. A composition of matter comprising a white mineral oil obtained by.strong acid refining containing dissolved therein, in an amount sufllcient to reduce substantially the tendency of the oil to form acidic material through oxidation, beta naphthyl mercaptan.

REGINALD G. SLOANE.