DE720380C - lubricant - Google Patents

Description

The invention relates to lubricants made from hydrocarbon oils to which a small amount of benzoic acid is added to improve film strength.
It is already known to improve the lubricating properties or the film strength of lubricants made from hydrocarbon oils by adding small amounts of one or more chemical substances to them. For example, halogenated organic compounds (such as chloroacetic acid or benzyl chloride), phosphorus compounds (e.g. triicresyl phosphate), sulfur-containing compounds, ketones, certain aliphatic acids and free fatty acids come into consideration for this purpose. However, these substances have the disadvantage of corroding the metal surfaces in the presence of moisture or of forming undesirable resinous oxidation products.

It is also known to use fatty oils as additives for lubricants. Such Lubricant blends are unsatisfactory, however, as fatty oils tend to become unstable, especially when the lubricant is exposed to elevated temperatures.

It is also known to add trioxymethylene to lubricating oils. It should through this resinification of the lubricant at elevated temperatures can be avoided. An improvement in film strength makes noticeable here only to a small extent; in addition, the metal surfaces attacked by trioxymethylene.

Another suggestion is to use benzaldehyde or salicylaldehyde as an additive to be used for lubricants made from hydrocarbon oils. This creates lubricants which are characterized by a high film

are strong and do not attack the metal surfaces.

According to the invention, similar successes are achieved with increased film strength, if the lubricants from hydrocarbon oils contain a small amount (for example ο, οΐ to 2 percent by weight) of benzoic acid added will.

The high film strength of a lubricant mixed with benzoic acid was demonstrated on a high pressure lubricant tester. This device indicates the pressure at which the film ruptures, which is formed by a lubricant and where there is direct metal-to-metal contact. For this purpose, the device is equipped with split bearings made from cold-rolled steel. Each storage _o half carries here the total burden of on

«Ο the storage unit of static pressure. The pressure is exerted by weights via a lever arrangement. A test shaft made of ground, unhardened steel moves in the bearing at a speed of 100 rev / min. The two bearing halves, which are loosely held together, are provided with so much lubricant in the bearing housing that the bearing surfaces are completely immersed in it. The device is initially loaded with light pressure. The pressure is then increased at intervals of 10 to 10 seconds, so that a pressure increase of around 140 kg / cm ^{2 is} achieved at each pressure level. The pressure load is increased until the shaft jams in the test bearing. The load is then measured which is resting on the bearing at the time the shaft is stuck. After completing the test, the shaft is checked for corrosion. To do this, it is placed in a closed vessel for several days, the inner air space of which is saturated with water vapor.

The improved film strength of lubricants mixed with benzoic acid Hydrocarbon oils are shown in the table below.

ι% stearic acid. Compression pressure per kg, cm ²
on sliding surfaces of the lubricant ι% oleic acid Camp at the time
of seizing from hydrocarbon oil of
a viscosity of 6.31 ⁰ E ι% nitrotoluene .. the wave ι% benzyl alcohol. 506 oei 37ö ι ° / o benzoic acid. 506 Oil without additives 73-2 Oil + 1250 oil + 1480 Oil + 2780 Oil + Oil +

Examination of the test waves for corrosion showed that they mixed with benzoic acid Lubricants did not have a corrosive effect on the metal surface.

The addition of benzoic acid is possible with all viscosity grades and also with lubricating greases effective.

Claims (1)

Claim: Lubricants made from hydrocarbon oils and a small addition of others chemical substances, characterized in that the additive consists of benzoic acid. BERLIN. PRINTED IN THE