US2217173A

US2217173A - Stabilized high film strength lubricating oil

Info

Publication number: US2217173A
Application number: US64706A
Authority: US
Inventors: Bert H Lincoln; Waldo L Steiner
Original assignee: Continental Oil Co
Current assignee: ConocoPhillips Co
Priority date: 1936-02-19
Filing date: 1936-02-19
Publication date: 1940-10-08
Anticipated expiration: 1957-10-08

Description

' aster Got. arose 3 m #1 sTRENG'EH GATING 01L am n. Lincoln and Waldo a. Steiner, Fonca (lity, Ghia; assignors to Continental on Company, ronca City, @lria a aeration oi Delaware No Drawing. Application February 19, 1935,

Se No. 643% Our invention relates to a stabilized high film strength lubricating oil, and more particularly to a composition of matter comprising a hydrocarbon oil of increased film strength obtained by S the addition of a chlorinated organic compound,

which composition has been stabilized.

It is known'that the addition of small quantities of chlorinated organic compounds in general to a hydrocarbon oil will impart thereto an in- 3Q creased film strength. As ordinarily prepared, the chlorinated carbon compounds are refined after chlorination by blowing with air to remove excess chlorine and hydrochloric acid. The chlorinated compounds are then given a wash with a solution of a reducing or om'dizing agent to remove labile chlorine. After water washing and drying, the chlorinated compounds are fairly stable with respect to the development of hydrochloric acid in storage. 'Ihe degree of stability is so, largely dependent on the severity of the oxidizing or reducing treat given. The. severity oi this treat in turn isgoverned by the amount of treating loss which ensues with said treating. in order to economically refine a chlorinated com- 25 pound as for example, a chlorinated ester of a. fatty acid, this treating should not be too severe. Therefore, the finished product is never as stable as is desired especially if it is to be stored in iron containers during the warm months of the year. 89. What is true of'the chloro-ester is true broadly for all chlorinated organic compounds in general. We find that chlorinated communds and esters in particular, stored under these conditions, quite often develop hydrochloric acid in a few weeks 85. time. When this occurs the product turns dark and some of the esters hydrolize, thereby increasing the free fatty acid. This is obviously objectionable. I When samples of the ordinarily repared and do refined chloro-esters are expose sunlight, either directly or indirectly, for a days in glass containers, some hydrochloric acid develops and tends to cause hydrolysis. This is analogous to the development of hydrochloric acid in the as dark in iron containers during the warm months. A test was developed to correlate the stability of the chloro-esters in sunlight and the stability in iron containers. Standard one-pound grease cans were cleaned and 25 cc. of the chloro-este'rs 50 to'be tested were poured into them. The cans *were then held at 240 F. until'they developed hydrochloric acid and tm-neddark. It was found that 1 hours without change at 240 F. in this test was equivalent to about three weeks exposure to indirect sunlight.

We have found that a number of compounds, when added to halogenated organic compounds in small amounts, greatly increased the period of time which was required to induce the formation of hydrochloric'acld' under the conditions of these two tests. The compoundswhich had the greatest effect were the terpene hydrocarbons. In particular, pinene was found to be an extremely potent stabilizer. For example, the straight methyl chloro stearate developed a strong odor of hydrochloric acid in less than a month's time. A blend of one per cent of pinene in the same' chloro-ester did not develop a trace of hydrochloric acid after a years exposure. The length of time before which hydrochloric acid developed in the iron can test at 240 F. described above, was increased by 900 per cent by the addition of one per cent of pinene.

Other terpene hydrocarbons which can be employed are myrcene, ocimene, limonene, hemiterpenes, dl-terpenes, polyterpenes, and the like. Terpene derivatives are also of value although they are not as effective as the hydrocarbons. Examples of these are geraniol, citronellol, cineol, carvine, citrol, and the like.

A second class oi compounds which we have discovered very effective as stabilizers for halogenated compounds was the hydrogenated derivatives of naphthalene, di-, tetrahexa-, octo-, and deca-hydronaphthalene. For example, one per cent of tetra-hydronaphthalene improved the sta-I billty of methyl chloro stearate 800 percent in the test, where the samples were exposed to sunlight.

A third class of compounds which has considerable stabllimng influence on halogenated compounds are the hydroxy aromatic compounds. One per cent of phenoLpara-cresol, naphthol, and para-hydroxy diphenyl each increased the stability of the chloro esters by 500 to 90 Per cent- Derivatives of the phenols are also operative. One per cent of crtho nitro phenol increased the stability of methyl chloro stearate by 800 per cent.

While a number of other compounds have some stabilizing influence on chloro-esters, the above three groups are outstanding. Three compounds not included in these groups, which have considerable merit, are cholesterol, ethyl abietate, and acetyl. Compounds which react with hydrochloric acid easily and hold the halogen acid firmly have been found to be of advantage in practicing our' invention. some ofthe other halogenated organic compounds which have been stabilized by the previously mentionedstabilizing agents are:

ogenated aliphatic hydrocarbons such as halogenated wax and halogenated petroleum oils: halogenated aromatic hydrocarbons such as halogenated benzene, naphthylene, diphenyl anthracene, and the like; halogenated aliphatic, aromatic, and hetero cyclic alcohols, aldehydes, ketones, acids, esters, ethers, 'etc.: mixtures of various halogenated organic compounds with each other and with amines, nitro compounds, phosphorous containing compounds, 'thio compounds.

etc.- 1

In practicing this invention, quantities oi the stabilizer of as small as .01 per cent 01 the chic rinated carbon compound content may be used with some good eiiects. The more of the stabilizer used with the chloro-ester, the more stable the resulting blend will be. however, the near maximum eil'ect is obtained with one per cent or less. For example, .1 per cent of pinene increased the stabilltyfin the iron can test 100 per cent, while .25 per cent increased the stability 500 per cent and one per cent increased the stability only 900 per cent.

- For each stabilizer there is a percentage which is most eflective in improving the'stability most economically. The stabilizer may be incorporated into the halogenated organic compound at any period during, its manufacture after air blowing (following chlorination) to remove excesschlorine. It is prei'erab1e ,-however, to add it immediately after the final drying process.

The stabilizers described in this invention not only act eilfectively in stabilizing organic chlorine compounds'in general, and especially chloroesters of fatty acids, but also reduces the corrosiveness of blends of halogenated organic compounds in lubricating oil. For example, a blend of one per cent oi. fairly stable methyl chloro stearate in oil caused a loss of 20 mg..per 100 sq. cm. 01' bearing metal in a corrosion test, conducted at 300 F. for forty-eight hours. A blend of one per cent of the same ester stabilized with .onepercentotpineneinoilinthesametest caused a loss of 8 mg. per 100 sq. cm. or the same bearing material. .Theretore, the stabilizer in the chloro ester gives a lubricating oil blend of improved stability.

Having thus described our invention, what w claim is? 1. A composition of matter comprising in combination a major portion of hydrocarbon oil,

from .5 o! 1% to 10% by weight of an aliphatic .00101 1% to 1% by weight of pinene.

BERT H. ransom. war-13o L. s'rnmna.