Lubricating Oil Formulation

Abstract
A lubricating oil formulation particularly useful in an internal combustion engine, comprising hydrofine paraffinic distillate from 10-30% v/v, castor/linseed oil from 5 to 40% v/v, aliphatic alcohol from 10-20% v/v and chlorinated paraffin from 10-30% v/v.
Description
FIELD OF THE INVENTION

The invention relates generally to the field of lubrication, and more generally, to the field of lubricating oil formulations.


BACKGROUND OF THE INVENTION

A typical lubricating oil formulation (e.g. standard motor oil) has lubrication as its primary function, but it also performs a number of other functions that are vital to the life and performance of fuel combustion engine. For example, in applications such as the internal combustion engine (“ICE”) oil dissipates heat and makes parts run cooler; it helps to reduce engine noise; it combats rust and corrosion of metal surfaces; it acts as a seal for pistons, rings, and cylinder walls; it combines with the oil filter to remove foreign substances from the engine.


When combustion occurs, temperatures can reach 2000-3000° F. (1093-1648° C.), while pistons can easily reach a temperature of 1000° F. (537° C.). The high heat load travels down the connecting rods to the bearings. Oil in the crankcase can reach 250° F. (121° C.) after warm-up and is supplied to the bearings at these temperatures.


There are a number of patent and non-patent references that describe the current state of the art of lubricating oil formulations. These include:



















U.S. Pat. No. 4,178,258
December, 1979
Papay et al.



U.S. Pat. No. 4,360,438
November, 1982
Rown et al.



U.S. Pat. No. 4,846,983
July, 1989
Ward, Jr.



U.S. Pat. No. 5,744,430
April, 1998
Inoue et al.



U.S. Pat. No. 6,855,675
February, 2005
Yamada, et al.



U.S. Pat. No. 6,884,761
April, 2005
Godici, et al.



U.S. Pat. No. 4,844,825
November, 1987
Sloan, et al.



U.S. Pat. No. 4,131,551
December, 1978
Thompson



U.S. Pat. No. 4,228,021
October, 1980
Lenack










Synthetics, Mineral Oils, and Bio-Based Lubricants, Leslie R. Rudnick, CRC Press, 2005.


Synthetic Lubricants and High Performance Functional Fluids. Leslie R. Rudnick and Ronald L. Subkin, CRC Press 1999.


Chemistry and Technology of Lubricants, R. M. Mortier, S. T. Orzulik, Springer 1997.


SUMMARY OF THE INVENTION

What is desired is a lubricating oil formulation showing improvement in at least one of the following areas: lubricating power, oxidation resistance, non-toxicity, boundary lubrication, friction modification, cooling and engine wall protection.


Therefore, according to the invention, there is provided a lubricating oil formulation comprising the following components: (1) hydrofine paraffinic distillate in an amount 10%-30% v/v; (2) castor oil in an amount 0%-40% v/v; (3) linseed oil in an amount 0%-40% v/v; (4) aliphatic alcohol in an amount 10%-20% v/v; and (5) chlorinated paraffin in an amount 10%-30% v/v; wherein the component (2) and the component (3) together are present in an amount 5%-40% v/v.







DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the preferred embodiment, the lubricating oil formulation comprises the following components: (1) hydrofine paraffinic distillate in an amount 10%-30% v/v; (2) castor oil in an amount 0%-40% v/v; (3) linseed oil in an amount 0%-40% v/v; (4) aliphatic alcohol in an amount 10%-20% v/v; and (5) chlorinated paraffin in an amount 10%-30% v/v; wherein the component (2) and the component (3) together are present in an amount 5%-40% v/v. In other words, the amount of component (2), added to the amount of component (3), is 5%-40% of the formulation v/v. Preferably, the castor oil and linseed oil are present in a 1:1 ratio (by volume). The following table shows three example formulations:















Component
% Example 1
% Example 2
% Example 3







Hydrofine
20
30
30


Paraffinic


distillate


Castor oil
20
20
15


Linseed oil
20
20
15


Aliphatic alcohol
20
20
20


Chlorinated
20
10
20


paraffin









Regarding the castor oil and linseed oil components, it will be appreciated that the polarity of ester molecules and acidic oils causes them to be attracted to one another and to other polar species, which has a direct impact on their performance. These substances exhibit low vapour pressures, low volatilities and high flash point. Because of their polar nature, they are excellent solvents, and are attracted to metal oxide layers on the surfaces of ICEs and the like, making them good boundary lubricants and friction modifiers. These molecules also have ester linkage with excellent thermal stability and resistance to oxygen molecule attack under relatively high temperatures. They also have low viscosity, and high viscosity indices.


Typical properties of these molecules are:


















Viscosity at 40° C. (cst)
 4-30



Viscosity at 100° C. (cst)
1-6



Viscosity Index
150-230



Pour Point (° C.)
−35 to +25



Flash point (° C.)
180-220



Oxidative Stability
Good



Biodegradability
Excellent










Their small sizes, combined with high polarities, make them effective solvents. Blending them with poly olefins (e.g. hydrofine paraffinic distillate) improves solubility and causes the blend to act as a seal swelling agent. Specifically, the blend diffuses into the elastomer of seals in ICEs, causing moderate expansion that improves seal performance. As well, castor and linseed oil molecules, having a high polarity and thus a higher affinity for metal oxide surfaces, have a greater tendency than less polar fluids (like mineral oils or synthetic hydrocarbons) to form adsorbed layers. Thus, castor and linseed oil have lower boundary friction coefficients. In the preferred formulation, the polar head of these molecules is anchored to the metal of surface of the ICE or other lubricated object, while the hydrocarbon tail is left solubilized in the lubricating oil formulation.


A benefit of the preferred form of the lubricating oil formulation is that it does not impede the functionality of elastomers with which it comes in contact. Thus, it does not make the elastomers soluble and prone to breakdown or loss of functionality, either by shrinkage or over-swelling.


In one embodiment, the castor oil component comprises 87%-90% ricinoleic acid w/w, 5%-7% oleic acid w/w, 1%-3% linoleic acid w/w, 1%-2% palmitic acid w/w and 1% stearic acid w/w. In one embodiment, the linseed oil component comprises of 6% palmitic acid w/w, 3.5% stearic acid w/w, 0.5% arachidic acid w/w, 19% oleic acid w/w, 24% linoleic acid w/w, 47% linolenic acid w/w.


The presence of paraffin oils (e.g. hydrofine paraffinic distillate) in combination with polar based oils (such as castor and linseed oils) offers greater oxidation resistance, reduced carbon sludge, effective operation at high temperatures, increased lubricity, higher film strength and consequently, reduced wear friction. These paraffin oils compliment the natural fatty acids in the polar oils by increasing the viscosity index of the lubricating oil formulation. Also, paraffinic oils are generally more compatible with elastomers and seals, and offer greater resistance to water emulsification (e.g. if water were to undesirably enter into an ICE). It has been found that hydrofine paraffinic distillates sold under the FAXAM 22™ trademark are well-suited for use in the formulation.


Preferably, the chlorinated paraffin ranges from C5 to C20. This component serves as a lubricant additive to improve the performance of the lubricating oil formulation under extreme pressure in an ICE or the like. Preferably, the chlorinated paraffin component comprises mixed chlorinated paraffins blended in mineral oil, which improves the shelf life of this component. Cereclor™ brand has been found to be well-suited for use in this formulation, and its typical properties are as follows:















Grade












A
B
C
D















Chlorine (% wt)
40
42
48
49


Density @25° C.
1.11
1.16
1.24
1.19


Viscosity @25° C.
0.7
25
280
0.8


(poise)


Viscosity @100° C. (cS)
4
32
70
4


Pour Point Approx. ° C.
−40
−30
−15
−30


Stability 4 hour
0.2
0.2
0.2
0.15


@175° C.


(% HCl released)









Regarding the aliphatic alcohol component of the formulation, it has been found that Exxal™ brand, produced by Exxon Mobil, is well-suited for use in this formulation. Typical properties of aliphatic alcohols are:




















Specific
Viscosity
Vapor
Flash
Pour



Boiling
Gravity
@ 20° C.
pressure
point
Point


Type
point ° C.
@20° C.
cSt
@100° C.
° C.
° C.





















Exxal 7
176
0.826
9.2
78 mmHg
>60
<−65


Exxal 8
193
0.833
13
27
>60
<−65


Exxal 9
215
0.836
17
16
>60
<−65


Exxal
224
0.838
21
 8
>93
<−65


10


Exxal
254
0.844
38
 5
>93
<−65


12


Exxal
266
0.848
49
 3
>93
<−65


13









Aliphatic alcohol is added as an antioxidant, metal scavenger, anti-foaming agent and emulsion stabilizer. It also acts as a solvent with lubricating properties.


Optionally, the formulation may include one or more alkyl benzenes, such as xylene or toluene, in an amount 0.1%-1% v/v. It has been found that this additive functions to reduce soot buildup inside the combustion chamber of the ICE, and clean engine cylinders and surrounding surfaces.


It will be appreciated that regarding the percent ranges given in relation to any component or ingredient, the component or ingredient may be present in any specific amount falling within that range, or within any sub-range falling within that range.

Claims
  • 1. A lubricating oil formulation comprising the following components: (1) hydrofine paraffinic distillate in an amount 10%-30% v/v; (2) castor oil in an amount 0%-40% v/v; (3) linseed oil in an amount 0%-40% v/v; (4) aliphatic alcohol in an amount 10%-20% v/v; and (5) chlorinated paraffin in an amount 10%-30% v/v; wherein the component (2) and the component (3) together are present in an amount 5%-40% v/v.
  • 2. A lubricating oil formulation, wherein the chlorinated paraffin component comprises mixed chlorinated paraffins from C5 to C20.
  • 3. A lubricating oil formulation of claim 1, wherein the castor oil and linseed oil are present in a 1:1 ratio by volume.
  • 4. A lubricating oil formulation as claimed in claim 1, wherein the castor oil component comprises 87%-90% ricinoleic acid w/w, 5%-7% oleic acid w/w, 1%-3% linoleic acid w/w, 1%-2% palmitic acid w/w and 1% stearic acid w/w.
  • 5. A lubricating oil formulation as claimed in claim 1, wherein the linseed oil component comprises of 6% palmitic acid w/w, 3.5% stearic acid w/w, 0.5% arachidic acid w/w, 19% oleic acid w/w, 24% linoleic acid w/w, 47% linolenic acid w/w.
  • 6. A lubricating oil formulation as claimed in claim 1, the formulation further comprising one or more alkyl benzenes in an amount of 0.1%-1% v/v.
  • 7. A lubricating oil formulation as claimed in claim 6, where the one or more alkyl benzenes comprise xylene, toluene, or a combination thereof.
CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No. 61/527486 filed Aug. 25, 2011, incorporated herein by reference in its entirety.

Provisional Applications (1)
Number Date Country
61527486 Aug 2011 US