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Claims  |
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What we claim is:
1. A trimethylol-propane ester composition useful as lubricant base for
motor-car engines, consisting essentially of the product obtained by total
esterification of trimethylolpropane by means of a diversity of saturated
aliphatic-hydrocarbyl carboxylic acids, said diversity having in a
proportion of 6 to 33% of the carboxy equivalents, at least one straight
or branched-chain dicarboxylic acid having from 4 to 19 carbon atoms, and
in a proportion of 94 to 67% of the carboxy equivalents, a mixture of
monocarboxylic acids, wherein said mixture of monocarboxylic acids
comprises:
a. from 10 to 70% by mole of at least one branched chain acid having from
15 to 22 carbon atoms and selected from the group consisting of those
having one methyl side chain, those having two methyl side chains, those
having one ethyl side chain, those having one methyl and one ethyl side
chains, and those having two ethyl side chains, and
b. from 90 to 30% by mole of at least one straight chain acid having from 7
to 22 carbon atoms.
2. A composition according to claim 1, wherein the branched chain acid is
obtained by isomerization of an olefinic fatty acid of 15-22 carbon atoms,
followed with hydrogenation.
3. A composition according to chain 1, wherein the branched chain acid is
isostearic acid.
4. A composition according to claim 1, wherein the dicarboxylic acid
contains 6-12 carbon atoms.
5. A composition according to claim 1, wherein in said diversity of
carboxylic acids, the proportion of dicarboxylic acid is from 13 to 33% of
the carboxy equivalents, and the proportion of monocarboxylic acid is from
87 to 67% of the carboxy equivalents.
6. In a synthetic ester based lubricating oil composition, comprising a
major proportion of a synthetic ester base oil and in amounts sufficient
to effect each additives attendant function of an antioxidant, viscosity
index improver and detergent-dispersant, the improvement comprising using
as the base oil the ester of claim 1.
7. A lubricating oil according to claim 6, wherein said viscosity index
improver is added in an amount sufficient to yield a final composition of
20 W 40 SAE multigrade oil.
8. A lubricating oil according to claim 6, wherein said viscosity index
improver is added in an amount sufficient to yield a final composition of
20 W 50 SAE multigrade oil.
9. The oil of claim 8, wherein the viscosity index improver comprises from
about 3% to about 6% by weight of said oil. pg,24
10. A trimethylol-propane ester composition according to claim 5 wherein
the dicarboxylic acid is adipic acid, and wherein the branched chain
monocarboxylic acid (a) is isostearic acid, and the straight chain
monocarboxylic acid (b) is heptanoic acid.
11. The lubricating oil of claim 6, comprising 89% by weight of said
trimethylol-propane ester base oil formed from adipic acid, isostearic
acid and heptanoic acid as said carboxylic acids; 4% by weight of an
ashless alkenylsuccinimide detergent dispersant additive; 2% by weight of
a phenate; 1% by weight of a zinc dithiophosphate; 1% by weight of
phenyl-.beta.-naphthylamine; and 3% by weight of a polymethacrylate
viscosity index improver.
12. A trimethylol-propane ester composition useful as lubricant base for
motor-car engines, consisting essentially of the product obtained by total
esterification of trimethylolpropane by means of a diversity of saturated
aliphatic-hydrocarbyl carboxylic acids, said diversity having in a
proportion of 6 to 33% of the carboxy equivalents, at least one straight
or branched-chain dicarboxylic acid having from 4 to 19 carbon atoms, and
in a proportion of 94 to 67% of the carboxy equivalents, a mixture of
monocarboxylic acids, said mixture comprising:
a. from 10 to 30% by mole of a branched chain acid containing 15-22 carbon
atoms and selected from the group consisting of those having one methyl
side chain, those having two methyl side chains, those having one ethyl
side chain, those having one methyl and one ethyl side chains, and those
having two ethyl side chains, and
b. from 40 to 60% by mole of straight-chain acid containing 7 to 9 carbon
atoms and from 20 to 40% by mole of straight chain acid containing 10 to
16 carbon atoms.
13. A composition according to claim 12, wherein the branched chain acid is
obtained by isomerization of an olefinic fatty acid of 15-22 carbon atoms,
followed with hydrogenation.
14. A composition according to claim 12, wherein the branched chain acid is
isostearic acid.
15. A composition according to claim 12, wherein the dicarboxylic acid
contains 6-12 carbon atoms.
16. A composition according to claim 12, wherein in the diversity of
carboxylic acids, the proportion of dicarboxylic acid is from 13 to 33% of
the carboxy equivalents, and the proportion of monocarboxylic acid is from
87 to 67% of the carboxy equivalents.
17. In a lubricating oil for motor-car engines, which comprises a major
proportion of a synthetic ester base oil and in amounts sufficient to
effect each additive's attendant function of viscosity index improver,
antioxidant and detergent-dispersant the improvement comprising using as
the base oil, the ester of claim 12.
18. A lubricating oil according to claim 17, wherein said viscosity index
improver is added in an amount sufficient to yield a final composition of
20 W 40 SAE multigrade oil.
19. A lubricating oil according to claim 17, wherein said viscosity index
improver is added in an amount sufficient to yield a final composition of
20 W 50 SAE multigrade oil.
20. The oil of claim 19 wherein the viscosity index improver comprises from
about 3% to about 6% by weight of said oil.
21. A trimethoylol-propane ester composition according to claim 16 wherein
the dicarboxylic acid is adipic acid, azelaic acid, or dodecanedioic acid,
the straight chain monocarboxylic acid of 7-9 carbon atoms is heptanoic
acid, the straight chain monocarboxylic acid of 10-16 carbon atoms is
lauric acid or a cut of fatty acids from coconut oil, and the branched
chain monocarboxylic acid of 15-22 carbon atoms is isostearic acid.
22. The lubricating oil of claim 17, comprising 87.5% by weight of said
trimethylol-propane ester base oil formed from adipic acid, heptanoic
acid, a mixture of saturated straight-chain aliphatic monocarboxylic acid
having from 10 -16 carbon atoms, and isostearic acid; 5% by weight of an
ashless alkenylsuccinimide detergent dispersant additive: 3% by weight of
a phenate; 0.5% by weight of zinc dithiophosphate; 1% by weight of
phenyl-.beta.-naphthylamine; and 3% by weight of a polymethacrylate
viscosity index improver.
23. The lubricating oil of claim 17, comprising 83% by weight of said
trimethylol-propane ester base oil formed from adipic acid, heptanoic
acid, lauric acid, and isostearic acid; 4% by weight of an ashless
alkenylsuccinimide detergent-dispersant additive; 3% by weight of a
phenate sulfide; 2% by weight of calcium sulfonate; 1% by weight zinc
di-thiophosphate; 1% by weight of phenyl-.beta.-napthylamine; and 6% by
weight of a polymethacrylate viscosity index improver.
24. The lubricating oil of claim 17, comprising 86% by weight of said
trimethylol-propane ester base oil formed from azelaic acid, heptanoic
acid, a mixture of straight-chain saturated aliphatic monocarboxylic acids
having 10-16 carbon atoms, and isostearic acid; 4% by weight of an ashless
alkenylsuccinimide detergent dispersant additive; 2% by weight of a
phenate sulfide; 1% by weight of zinc dithiophosphate; 1% by weight of
phenyl-.beta.-naphtylamine; and 5% by weight of a polymethacrylate
viscosity index improver.
25. The lubricating oil of claim 17, comprising 84.5% by weight of said
trimethylol-propane ester base oil formed from adipic acid, heptanoic
acid, lauric acid, and isostearic acid; 4% by weight of an ashless
alkenylsuccinimide detergent dispersant additive; 2% by weight of calcium
sulfonate; 2% by weight of phenate sulfide; 1.5% by weight of zinc
di-thiophosphate; 1% by weight phenyl-.beta.-naphtylamine; and 5% by
weight of a polymethacrylate viscosity index improver. |
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Claims |
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Description |
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This invention concerns new synthetic lubricating bases and motor-oils
obtained therefrom.
It is well-known that trimethylol-propane esters are widely used as
lubricants for aircraft. In the past few years, it has been proposed to
use them also for manufacturing oils for motor-car engines, but the
trimethylol-propane esters which are commonly manufactured for use in
aircraft, have low viscosities, of 3 to 7 cST at 98.9.degree. C, so that
they are not satisfactory for use as motor oils whose viscosity must be
usually far higher than 7 cSt at 98.9.degree. C.
It has thus been proposed to thicken them with viscosity additives, so as
to form lubricants satisfying at least the standard of the SAE 30 category
(viscosity at 98.9.degree. C = 10 cSt). This has at least two
disadvantages:
The base oil is highly volatile,
The necessary amount of viscosity additive is very high.
These two disadvantages might be obviated if a mixture of
trimethylol-propane esters were available, whose viscosity at 98.9.degree.
C is high, for example higher than 8 cSt.
It is difficult, particularly for cost reasons, to prepare a simple ester
(or a mixture of simple esters) of trimethylolpropane having a high
viscosity and a low pour point.
Conversely, it is easier to obtain such a result by preparing a mixture of
complex trimethylol-propane esters by esterification of this triol by
means of a mixture of mono- and dicarboxylic acids, although the
compositions of this type, as described in the priorr art, have a major
disadvantage: due to their high content of ester groups, they do not
easily dissolve additives, such as those commonly employed in motor oils
of a mineral base.
We have now discovered surprisingly that it is possible to manufacture
trimethylolpropane ester compositions having both a high viscosity and a
considerably increased dissolving power with respect to the conventional
additives, as well as a low pour point; such ester compositions are thus
well adapted to the formulation of multigrade oils also containing a low
proportion of viscosity index improvers.
As a rule, the ester compositions of the invention consist essentially of
products obtained by total esterification of trimethylolpropane with
mixtures of saturated aliphatic carboxylic acids consisting, in a
proportion of 6 to 33% of the carboxy equivalents, of one or more straight
or branched dicarboxylic acid comprising from 4 to 19 carbon atoms, and,
in a proportion of 94 tp 67% of the carboxy equivalents, of a mixture of
monocarboxylic acids comprising from 2 to 30 carbon atoms, these ester
compositions being characterized in that said mixture of monocarboxylic
acids comprises (a) from 5 to 90% by mole of at least one weakly branched
acid comprising 15-30 carbon atoms, and (b) 95 to 10% by mole of at least
one straight chain acid comprising from 2 to 30 carbon atoms.
According to the invention, the weakly branched monocarboxylic acids are
saturated aliphatic monocarboxylic acids whose chain has one or at most
two branches having 1 or 2 carbon atoms. They preferably comprise from 15
to 22 carbon atoms. The acids obtained by isomerization of olefinic fatty
acids, followed with a hydrogenation, are of particular interest; they
contain as an average one methyl branch per molecule. The liquid acids
obtained by hydrogenation of the by-products from the polymerization of
olefinic fatty acids, for example according to the method described in
U.S. Pat. No. 2,812,342, are particularly convenient, for example
isostearic acid, as obtained from a starting olefinic fatty acid
containing 18 carbon atoms.
Among the dicarboxylic acids, as hereinbefore defined, we prefer to use,
according to the invention, those which comprise from 6 to 12 carbon
atoms, for example: adipic acid, methyl adipic acids, azelaic acid,
trimethyladipic acids, sebacic acid and dodecanedioic acid.
Among the straight chain monocarboxylic acids, as hereinbefore defined, we
prefer to use, according to the invention, those which comprise from 7 to
22 carbon atoms, for example heptanoic acid, pelargonic acid, lauric acid
or fatty acid fractions having a high content of lauric acid.
On the other hand, we have found that the most advantageous ester
compositions according to the invention are those which are obtained by
esterifying trimethylol propane completely by means of mixtures of
carboxylic acids in the following proportions:
dicarboxylic acids: from 13 to 33% of carboxy equivalents,
monocarboxylic acids: from 87 to 67% of carboxy equivalents among which the
molar proportion of weakly branched monocarboxylic acids comprising 15 to
22 carbon atoms is usefully 10 to 70% and the molar proportion of straight
chain monocarboxylic acids comprising 7-22 carbon atoms is from 90 to 30%.
A particularly advantageous composition of all the monocarboxylic acids may
comprise for example, per each 100 moles, from 10 to 30 moles of weakly
branched acid having 15-22 carbon atoms, from 40 to 60 moles of straight
chain acids comprising 7-9 carbon atoms and from 20 to 40 moles of
straight chain acids comprising from 10 to 16 carbon atoms.
The trimethylol propane ester compositions according to the invention, may
be prepared according to any conventional esterification method, making
use of the carboxylic acids, as such, their halides, for example their
chlorides or bromides, their anhydrides or their lower alkyl esters,
optionally in the presence of a conventional esterification or
transesterification catalyst, euch as paratoluenesulfonic acid, with the
removal of any water and/or alcohol as formed.
The ester compositions according to the invention constitute lubricating
bases of high viscosity,. Their viscosity at 98.9.degree. C is usually
higher than 8 cSt. They very easily dissolve the conventional additives,
such as those conventionally employed in motor oils of mineral base,
specifically antioxidant additives and ash-containing and ashless
detergent-dispersant additives. They are thus quite adapted to the
formulation of multigrade oils of, for example, the 20 W 40 and 20 W 50
SAE types, while additives improving the viscosity index are also added,
but in small amounts.
The following examples illustrate the invention.
Isostearic acid, of commercial grade, as used in examples 1, 3, 4 and 6 to
9 has the following characteristics:
Average molecular weight: 310
Acid index: 0.18 g of KDH per gram of material.
Average branching number: about 1 side methyl group per molecule.
In the examples of multigrade oil compositions the following additives have
been used:
Antioxidant additives:
phenyl-beta-naphthylamine
"OLOA 267" zinc di-thiophosphate
Ash containing detergent dispersant additives:
"OLOA 246 B" calcium sulfonate of TBN = 18 mg/g
"Lubrizol" phenate of TBN = 210 mg/g
"OLOA 216" phenate of TBN = 112 mg/g
"OLOA 218 A" phenate sulfide of TBN = 148 mg/g
Ashless detergent-dispersant additives:
Lubrizol 890 of TBN = 23.5 mg/g (alkenylsuccinimide)
"OLOA 1200" of TBN = 45 mg/g (alkenylsuccinimide)
"OLOA 4373" of TBN = 25 mg/g (alkenylsuccinimide)
"TEXACO TLA 202"
Viscosity index improvers (polymethyacrylates):
"Garbacryl T 70" and "D 42" (Rhone-Progil)
TBN, as used above, means total base number, as expressed in mg of
potassium hydroxide per gram of product.
Examples 2, 5, 9, 12 and 15 are given for comparison.
EXAMPLE 1
A mixture of 134 g (1 mole) of trimethylolpropane, 36.5 g (0.25 mole) of
adipic acid, 130 g (1 mole) of heptanoic acid and 465 g (1.5 mole) of
isostearic acid is esterified according to a conventional process.
Isostearic acid amounts to 60% by mole of all the monocarboxylic acids.
The resulting ester has the following properties:
viscosity at -17.8.degree. C: 57 poises
viscosity at 98.9.degree. C: 13.16 cSt
viscosity index VI.sub.E : 135
pour point: -32.degree. C
EXAMPLE 2
By way of comparison, an ester whose properties were nearly those given in
example 1, except that it did not contain isostearic acid, has been
prepared by esterifying a mixture of 134 g (1 mole) of trimethylolpropane,
73 g (0.5 mole) of adipic acid and 260 g (2 moles) of heptanoic acid. The
resulting ester had the following properties:
viscosity at -17.8.degree. C: 48 poises
viscosity at 98.9.degree. C: 12.6 cSt
viscosity index VI.sub.E : 138
pour point: -40.degree. C
EXAMPLE 3
We have esterified in the same manner a mixture of 134 g (1 mole) of
trimethylolpropane, 51.1 g (0.35 mole) of adipic acid, 119.6 g (0.92 mole)
of heptanoic acid, 141.4 g (0.69 mole) of a mixture of saturated straight
chain aliphatic monocarboxylic acids having from 10 to 16 carbon atoms
(fatty acid from coconut oil) and 214 g (0.69 mole) of isostearic acid.
The C.sub.10 - C.sub.16 acid mixture and isostearic acid each represent
27.6% by mole of all the monocarboxylic acids. The properties of the
resulting ester are the following:
viscosity at -17.8.degree. C: 38 poises
viscosity at 98.9.degree. C: 12.34 cSt
viscosity index VI.sub.E : 146
pour point: -28.degree. C
EXAMPLE 4
We have esterified in the same manner a mixture of 134 g (1 mole) of
trimethylolpropane, 54.75 g (0.375 mole) of adipic acid, 117 g (0.9 mole)
of heptanoic acid, 180 g (0.9 mole) of 93% lauric acid and 139.5 g (0.45
mole) of isostearic acid. Lauric acid represents 40% and isostearic acid
20% by mole of all the monocarboxylic acids. The characteristics of the
resulting ester are the following:
viscosity at -17.8.degree. C: 37 poises
viscosity at 98.9.degree. C: 12.26 cSt
viscosity index VI.sub.E : 148
pour point: -32.degree. C
EXAMPLE 5
By way of comparison, an ester having properties similar to those of the
ester of example 4, except that it did not contain isostearic acid, has
been prepared by esterification of a mixture of 134 g (1 mole) of
trimethylolpropane, 54.75 g (0.375 mole) of adipic acid, 146.25 g (1.125
mole) of heptanoic acid, and 225 g (1.125 mole) of 93% lauric acid
The properties of the resulting ester are the following:
viscosity at -17.8.degree. C: 35 poises
viscosity at 98.9.degree. C: 10.7 cSt
viscosity index VI.sub.E : 152
pour point: -32.degree. C
EXAMPLE 6
We have esterified in the same way a mixture of 134 g (1 mole) of
trimethylolpropane, 65.8 g (0.35 mole) of azelaic acid, 166 g (1.035 mole)
of heptanoic acid, 188 g (0.92 mole) of a mixture of straight chain
saturated aliphatic monocarboxylic acids having 10-16 carbon atoms (fatty
acids of coconut oil) and 107 g (0.345 mole) of isostearic acid. The
mixture of C.sub.10 - C.sub.16 acids amounts to 40% and isostearic acid to
15% by mole of all the monocarboxylic acids.
The properties of the resulting ester are the following:
viscosity at -17.8.degree. C: 35 poises
viscosity at 98.9.degree. C: 12.45 cSt
viscosity index VI.sub.E : 152
pour point: -27.degree. C
EXAMPLE 7
We have esterified as usually 134 g (1 mole) of trimethylolpropane with 69
g (0.3 mole) of dodecane dioic acid, 143 g (1.1 mole) of heptanoic acid,
180 g (0.9 mole) of lauric acid and 124 g (0.4 mole) of isostearic acid.
Lauric acid amounts to 37.5% and isostearic acid to 16.7% by mole of all
the monocarboxylic acids.
The resulting ester has the following properties:
viscosity at -17.8.degree. C: 27 poises
viscosity at 98.9.degree. C: 11.95 cSt
viscosity index VI.sub.E : 159
pour point: -28.degree. C
EXAMPLE 8
We have esterified a mixture of 12.06 kg (90 moles) of trimethylolpropane,
3.94 kg (27 moles) of adipic acid, 13.16 kg (101.25 moles) of heptanoic
acid, 13.95 kg (69.75 moles) of lauric acid and 13.93 kg (45 moles) of
isostearic acid. Lauric acid amounts to about 32.3% and isostearic acid to
about 20.8% by mole of all the monocarboxylic acids. We have obtained 50.6
kg of an ester whose properties are as follows:
viscosity at -17.8.degree. C: 25.5 poises
viscosity at 98.9.degree. C: 9.88 cSt
viscosity index VI.sub.E : 148
pour point: -34.degree. C
EXAMPLE 9
By way of comparison, we have esterified a mixture of 134 g (1 mole) of
trimethylolpropane, 36.5 g (0.25 mole) of adipic acid, 13 g (0.1 mole) of
heptanoic acid and 744 g (2.4 moles) of isostearic acid. Isostearic acid
amounts to 96% by mole of all the monocarboxylic acids. The resulting
ester has the following properties:
viscosity at -17.8.degree. C: 62 poises
viscosity at 98.9.degree. C: 15.3 cSt
viscosity index VI.sub.E : 143
pour point: -20.degree. C
The esters, as prepared according to examples 1 to 8, have viscosity
properties which make them quite useful for use as base lubricants for
multigrade oils. Their pour point is also sufficiently low. Conversely,
the ester prepared as described in example 9 with too high a proportion of
isostearic acid has too high a pour point.
TEST No. 1: Additive solubilization.
We have attempted to separately dissolve various known detergent-dispersant
additives, as identified in Table I by their trade mark reference, into
the esters prepared according to examples 1, 8 and also 5. The tests have
been conducted at -15.degree. C and at room temperature (+20.degree. C)
and conventional concentrations have been employed.
TABLE I
__________________________________________________________________________
Ester of example
Composition 1 8 5
__________________________________________________________________________
Diacid (% COOH equ.)
17 20 25
Monoacids (% COOH equ.)
83 80 75
Isostearic acid/total
monoacids (% moles) 60 20.8 0
Additives SOLUBILITY*
Ash-containing detergent-dispersants
-15.degree. C
+20.degree. C
-15.degree. C
+20.degree. C
-15.degree. C
-20.degree. C
__________________________________________________________________________
OLOA 246 B
2 % b.w. yes yes yes yes no no
OLOA 216 3 % b.w. yes yes yes yes no no
OLOA 218 A
3 % b.w. yes yes yes yes no no
Ashless-detergent-dispersants
Lubrizol 890
4 % b.w. yes yes no yes no no
OLOA 1200 4 % b.w. yes yes no yes no no
OLOA 4373 4 % b.w. yes yes yes yes no yes
__________________________________________________________________________
*yes = the mixture is perfectly clear at the temperature
no = the mixture is turbid and separates at the temperature indicated.
The results of Table I show that the ester of example 5 cannot be used to
dissolve the required amounts of conventional detergent-dispersant
additives.
In the following examples 10 to 17, esters prepared according to examples 1
to 6 and 8, have been used as base oils for multigrade oil compositions,
further containing:
the amount of viscosity index improvement additive necessary to attain the
desired SAE category;
the usual amounts of antioxidant additives and detergent-dispersant
additives.
EXAMPLE 10
By using the ester of example 1, we have formulated a lubricating oil by
admixing:
Lubrizol 890: 4g
Lubrizol phenate: 2g
Oloa 267: 1g
Phenyl-.beta.naphthyl amine: 1g
Garbacryl T 70: 3g
Ester of example 1: 89g
The mixture remains perfectly clear after storage for a long period at
-15.degree. C and has the following properties:
viscosity at -17.8.degree. C : 79 poises
viscosity at 98.9.degree. C : 19.9 cSt
viscosity index VI.sub.E : 153
pour point : -31.degree. C
Sae type : 20 W 50
EXAMPLE 11
We have used the same ester to manufacture the following lubricating
composition:
Oloa 1200: 4g
Texaco TLA 202: 3g
Oloa 246 B: 2g
Phenyl-62 naphthylamine: 1g
Garbacryl D 42: 4g
Ester of example 1: 86g
The mixture is perfectly clear at -15.degree. C and has the following
properties:
viscosity at -17.8.degree. C : 86 poises
viscosity at 98.9.degree. C : 20.8 cSt
viscosity index VI.sub.E : 153
pour point : -32.degree. C
Sae type : 20 W 50
EXAMPLE 12
By way of comparison, we have attempted to prepare the same mixture with
the ester of example 2, free of isostearic acid. The mixtures are very
turbid and settle quickly with clear separation of several phases, even at
room temperature (+20 .degree. C). The properties could not be determined.
EXAMPLE 13
The following lubricating composition has been formulated with the ester of
example 3.
Lubrizol 890: 5g
Oloa 216: 3g
Oloa 267: 0.5g
Phenyl-.beta. naphthylamine: 1g
Garbacryl D 42: 3g
Ester of example 3: 87.5g
The mixture is perfectly clear when stored at -15.degree. C and has the
following properties:
viscosity at -17.8.degree. C : 64 poises
viscosity at 98.9.degree. C : 18.45 cSt
viscosity index VI.sub.E : 155
pour point : -29+ C
Sae type : 20 W 50
EXAMPLE 14
The following lubricating composition has been prepared with the ester of
example 4 :
Oloa 1200: 4g
Oloa 218 A: 3g
Oloa 246 B: 2g
Oloa 267: 1g
Phenyl-.beta. naphthylamine: 1 g
Garbacryl D 42: 6g
Ester of example 4: 83g
The mixture is perfectly clear after storage at -15.degree. C and has the
following properties:
viscosity at -17.8.degree. C : 64 poises
viscosity at 98.9.degree. C : 22.1 cSt
viscosity index VI.sub.E : 169
pour point : -32.degree. C
Sae type : 20 W 50
EXAMPLE 15
By way of comparison, we have made the same mixtures with the ester of
example 5, free of isostearic acid. The mixtures are turbid and settle at
room temperature (+20.degree. C). The properties could not be determined.
EXAMPLE 16
The following composition has been manufactured by using the ester of
example 6:
Oloa 1200: 4g
Oloa 218 A: 3g
Oloa 267: 1g
Phenyl-.beta. naphthylamine: 1g
Garbacryl T 70: 5g
Ester of example 6: 86g
The mixture remains perfectly clear at -10.degree. C and has the following
properties:
viscosity at -17.8.degree. C : 50 poises
viscosity at 98.9.degree. C : 22.3 cSt
viscosity index VI.sub.E : 180
pour point : -25.degree. C
Sae type : 20 W 50
TEST No. 2
We have subjected the lubricating compositions according to the invention
to the so-called Indiana tests, in order to determine their stability with
respect to oxidation. These Indiana tests are described in Industrial and
Engineering Chemistry, vol. 13 No. 5 (1941) p. 317-321 under the head
"Indiana Stirring Oxidation Test for Lubricating Oils".
According to these tests, the lubricant sample, free of viscosity additive,
is maintained at a temperature of 160.degree. C under strong stirring, in
the presence of air and copper and steel samples, for 72 hours. The
variation of the oil viscosity at 37.8.degree. C is determined, and also
its acid number, its content of copper and of matter insoluble in heptane.
The results given in Table II show the resistance to oxidation-corrosion
of the lubricating composition of example 13 (without Garbacryl D 32) and
also that of a composition available in the trade, based on a mineral oil
(tested for comparison).
TABLE II
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Oil of Mineral
example 13
base oil
______________________________________
Viscosity variation at 37.8.degree. C
. 24 h + 4.6 + 19.5
% . 48 h + 7.8 + 29.5
. 72 h + 9.5 + 81.2
Final acid number (mg/g)
2.4 5.6
Final content of
copper (ppm) 10 160
insoluble in heptane (%)
0.1 0.2
______________________________________
EXAMPLE 17
A lubricating oil has been prepared by means of the ester of example 8
containing:
Oloa 4373: 4g
Oloa 246 B: 2g Oloa 218 A: 2g
Oloa 267: 1.5g
Phenyl-.beta. naphthylamine: 1g
Garbacryl D 42: 5g
Ester of example 8: 84.5g
This oil has the following properties:
viscosity at -17.8.degree. C : 42.5 poises
viscosity at 98.9.degree. C : 17.39 cSt
viscosity index VI.sub.E : 168
pour point : -27.degree. C
Sae type : 20 W 50
TEST No. 3
The oil of example 17 has been subjected to an oxidation-corrosion test on
a Peter W1 engine, which shows the corrosiveness of an oil with respect to
copper-lead bearings. The standard test takes 36 hours; it has been
continued beyond that time, in order to observe a great corrosion of the
bearings, corresponding to a loss of weight of more than 100 mg. The
losses of weight of the bearings in 36, 72 and 108 hours are given in the
following table III, which also gives, by way of comparison, the results
obtained with a synthetic ester base oil of the trade.
TABLE III
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Loss of weight of Oil of Oil
the Cu/Pb bearings in
example 13 of the trade
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36 hours 8 mg 40 mg
72 hours 35 mg 191 mg
108 hours 104 mg
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