Polymeric Poly-Phosphorus Additives for: Gear Oil, Grease, Engine-Oil, Combustion-Engine Lubricant, Automatic Transmission Fluid, Anti-Wear Agents, Two-Cycle Engine Lubricant, or Marine-Engine Lubricant

Abstract

A method having the step of using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

Description

BACKGROUND OF THE INVENTION

The following are all known: gear oils, greases, engine-oil additives, combustion-engine lubricants, automatic transmission fluids, anti-wear agents, two-cycle engine lubricants, and marine-engine lubricants. With all of them, there is a need for improved performance.

BRIEF SUMMARY OF THE INVENTION

A method having the step of using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; and wherein x is an integer ranging from 1 to 1000.

A method having the step of using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 2 to 100; and wherein x is an integer ranging from 1 to 1000.

A method having the step of using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 2 to 100; and wherein x is an integer ranging from 1 to 1000.

A method having the step of using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 2 to 100; wherein each Z is independently selected from the group consisting of S and O; and wherein x is an integer ranging from 1 to 1000.

A method having the step of using a copolymer compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein Y₁ and Y₂ are different; wherein each m is an independently selected integer ranging from 1 to 100; wherein each Z is independently selected from the group consisting of S, H, O, and nothing; and wherein each x is an independently selected integer ranging from 1 to 1000.

A method having the step of using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; and wherein x is an integer ranging from 1 to 1000.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1 is a picture of a Timken testing apparatus.

FIG. 2 is a graph showing Falex Pin and Vee Block test results.

FIG. 3 is a graph showing Falex Pin and Vee Block test results.

FIG. 4 is a graph showing Falex Pin and Vee Block test results.

FIG. 5 is a graph showing Falex Pin and Vee Block test results.

DETAILED DESCRIPTION OF THE INVENTION

Embodiments are directed to compounds that are useful as additives for: gear oil, grease, engine-oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, and marine-engine lubricant. The compounds are also useful as an anti-wear additive or anti-wear agent.

An embodiment is directed to polyhydrogen-phosphite compounds having the general structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety;

wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety;

wherein each m is an independently selected integer ranging from 1 to 100; and

wherein x is an integer ranging from 1 to 1000.

In some polyhydrogen-phosphite embodiments, each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

In some polyhydrogen-phosphite embodiments, the compound has a weight ranging from 1000 to 30000 Daltons. In some polyhydrogen-phosphite embodiments, the compound has a weight ranging from 400 to 30000 Daltons. In some polyhydrogen-phosphite embodiments, the compound has a weight ranging from 500 to 30000 Daltons.

An embodiment is directed to phosphate compounds having the general structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety;

wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety;

wherein each m is an independently selected integer ranging from 1 to 100; and

wherein x is an integer ranging from 1 to 1000.

In some phosphate embodiments, each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

In some phosphate embodiments, the compound has a weight ranging from 1000 to 30000 Daltons. In some phosphate embodiments, the compound has a weight ranging from 400 to 30000 Daltons. In some phosphate embodiments, the compound has a weight ranging from 500 to 30000 Daltons.

An embodiment is directed to thiophosphate compounds having the general structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety;

wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety;

wherein each m is an independently selected integer ranging from 1 to 100; and

wherein x is an integer ranging from 1 to 1000.

In some thiophosphate embodiments, each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

In some thiophosphate embodiments, the compound has a weight ranging from 1000 to 30000 Daltons. In some thiophosphate embodiments, the compound has a weight ranging from 400 to 30000 Daltons. In some thiophosphate embodiments, the compound has a weight ranging from 500 to 30000 Daltons.

An embodiment is directed to phosphorus-containing compounds having the general structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety;

wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety;

wherein each m is an independently selected integer ranging from 1 to 100;

wherein each Z is independently selected from the group consisting of S and O; and

wherein x is an integer ranging from 1 to 1000.

In some phosphorus-containing embodiments, each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

In some phosphorus-containing-compound embodiments, the compound has a weight ranging from 1000 to 30000 Daltons. In some phosphorus-containing embodiments, the compound has a weight ranging from 400 to 30000 Daltons. In some phosphorus-containing embodiments, the compound has a weight ranging from 500 to 30000 Daltons.

An embodiment is directed to phosphorus-containing copolymer compounds having the general structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety;

wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety;

wherein Y₁ and Y₂ are different;

wherein each m is an independently selected integer ranging from 1 to 100;

wherein each Z is independently selected from the group consisting of S, H, O, and nothing; and

wherein each x is an independently selected integer ranging from 1 to 1000.

In some phosphorus-containing copolymer embodiments, each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

In some embodiments, each Z is independently selected from the group consisting of S, H, and O.

In some phosphorus-containing copolymer compound embodiments, the compound has a weight ranging from 1000 to 30000 Daltons. In some phosphorus-containing copolymer compound embodiments, the compound has a weight ranging from 400 to 30000 Daltons. In some phosphorus-containing copolymer compound embodiments, the compound has a weight ranging from 500 to 30000 Daltons.

An embodiment is directed to phosphite compounds having the general structure:

wherein each R is an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety;

wherein each Y is an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety;

wherein each m is an independently selected integer ranging from 1 to 100; and

wherein x is an integer ranging from 1 to 1000.

In some phosphite embodiments, each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

In some phosphorus-compound embodiments, the compound has a weight ranging from 1000 to 30000 Daltons. In some phosphorus-containing copolymer compound embodiments, the compound has a weight ranging from 400 to 30000 Daltons. In some phosphorus-containing copolymer compound embodiments, the compound has a weight ranging from 500 to 30000 Daltons.

Methods for manufacturing any of the disclosed compounds that include phosphite compounds, polyhydrogen phosphite compounds, phosphate compounds, thiophosphate compounds, and thiophosphite-phosphate copolymer compounds can be determined by persons of ordinary skill in the art without having to exercise undue experimentation. Non-limiting examples of manufacturing methods can be found in the below Examples.

Any of the above compounds, either alone or in any combination, can be used as an additive for: gear oil, grease, engine-oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, or marine-engine lubricant. The compounds, either alone or in any combination, are also useful as anti-wear additives. For each of the described uses, useful amounts of the compound(s) can be determined by persons of ordinary skill in the art. As a non-limiting example, useful amounts of the above compounds, either alone or in any combination, range from 5 to 10% by weight of the fluid to which the compound(s) is being added. In an additional non-limiting example, useful amounts of the above compound(s), either alone or in any combination, range from 0.5 to 20% by weight of the fluid to which the compound(s) is being added.

In any of the above sulfur-containing compounds, the amount of sulfur within the compound can range from 50 to 100 mole percent relative to the amount of phosphorus within the compound; stated differently, in any of the above sulfur-containing compounds, anywhere from half to all of the phorphorus atoms are bonded to a sulfur atom. In another embodiment, the amount of sulfur within the compound can range from 90 to 100 mole percent relative to the amount of phosphorus within the compound. In another embodiment, the amount of sulfur within the compound is 100 mole percent relative to the amount of phosphorus within the compound.

Although all of the above compounds are taught as having alkylphenol-free moieties, in some embodiments, a compound's above-described alkylphenol-free moiety is replaced with an alkylphenol moiety. In other embodiments, more than one of a compound's above-described alkylphenol-free moieties is replaced with an alkylphenol moieties. Here is a non-limiting example of a compound containing an alkylphenol moiety:

wherein each R is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; and wherein x is an integer ranging from 1 to 1000.

Here is another non-limiting example of a compound containing an alkylphenol moiety:

wherein each R is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; and wherein x is an integer ranging from 1 to 1000.

Here is another non-limiting example of a compound containing an alkylphenol moiety:

wherein each R is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; and wherein x is an integer ranging from 1 to 1000.

Here is another non-limiting example of a compound containing an alkylphenol moiety:

wherein each R is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; wherein each Z is independently selected from the group consisting of S and O; and wherein x is an integer ranging from 1 to 1000.

Here is another non-limiting example of a compound containing an alkylphenol moiety:

wherein each R is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; wherein each Z is independently selected from the group consisting of S and O; and wherein each x is an independently selected integer ranging from 1 to 1000.

Here is another non-limiting example of a compound containing an alkylphenol moiety:

wherein each R is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_1-22 alkyl, C_6-40 cycloalkyl, C_3-20 methoxy alkyl glycol ether, C_3-20 alkyl glycol ether, or Y—OH moiety; wherein each Y is an independently selected alkylphenol moiety or an independently selected alkylphenol-free moiety that is a C_2-40 alkyl, C_6-40 cycloalkyl, C_2-20 alkyl glycol ether, or C_3-40 alkyl lactone moiety; wherein each m is an independently selected integer ranging from 1 to 100; and wherein x is an integer ranging from 1 to 1000.

In an embodiment, using a compound as an additive for gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent means adding the compound to a gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent. In another embodiment, using a compound as an additive for gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent means using the end composition that includes the compound as a gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent.

Examples I

TNPP-T (Trisnonyiphenyl Thiophosphate)

To a three-neck 250 mL flask equipped with a mechanical stirrer and purged with nitrogen was added 75.83 grams of triisnonylphenol phosphite (0.110 mol), with a total nonylphenol content ranging from 0.05% to 0.5% with 0.1% being the target and 0.39 grams of 2,5-dimercapto-1,3,4-thiadiazole (0.0026 mol). The mixture was mixed well and heat was applied to a reaction temperature of 240° F. 3.37 grams of elemental sulfur (0.130 mol) was then added at this temperature. After one hour, the reaction temperature is increased to 280° F. and held for 16-24 hours. This reaction takes place under a nitrogen blanket. The resulting thiophosphate had the following analysis:

% Phosphorous 4.5
% Sulfur      4.2
Density 20 C  1.01
Color, APHA   50
% Nonylphenol <0.20

LGP-11-T (Alkylphenol Free Polymeric Polyphosphite), U.S. Pat. No. 8,563,6378

To a three-neck 250 mL flask equipped with a mechanical stirrer and purged with nitrogen was added 75.83 grams of a alkylphenol-free liquid polymeric phosphite (Example #2 from U.S. Pat. No. 8,563,637), with a molecular weight of about 9100 and 0.39 grams of 2,5-dimercapto-1,3,4-thiadiazole (0.0026 mol). The mixture was mixed well and heat was applied to a reaction temperature of 240° F. Then 3.51 grams of elemental sulfur (0.109 mol) was added. After one hour, the reaction temperature is increased to 280° F. and held for 16-24 hours. This reaction takes place under a nitrogen blanket. The resulting alkyl phenol free polymeric thiophosphate had the following analysis:

% Phosphorous 4.7
% Sulfur      4.4
Density 20 C
Color, APHA   60
% Nonylphenol 0

LGP-12-T (Alkylphenol Free Cycloaliphatic Poly and Copoly Phosphites) U.S. Pat. No. 8,981,042B2

To a three-neck 250 mL flask equipped with a mechanical stirrer and purged with nitrogen was added 75.83 grams of cycloaliphatic polyphosphite (Example 2 from U.S. Pat. No. 8,981,042) with a molecular weight range of about 14,000 and 0.39 grams of 2,5-dimercapto-1,3,4-thiadiazole (0.0026 mol). The mixture was mixed well and heat was applied to a reaction temperature of 240° F. 5.52 grams of elemental sulfur (0.172 mol) was then added. After one hour, the reaction temperature is increased to 280° F. and held for 16-24 hours. This reaction takes place under a nitrogen blanket. The resulting analysis of the phenol free cycloaliphatic alkylated poly thiophosphate was:

% Phosphorous 7.2
% Sulfur      6.75
Color, APHA   50
% Nonylphenol 0

LGP(DPG)-11-T, U.S. Pat. No. 8,563,637E3

To a three-neck 250 mL flask equipped with a mechanical stirrer and purged with nitrogen was added 75.83 grams of a alkylphenol-free liquid polymeric phosphite (Example #3 from U.S. Pat. No. 8,563,637), with a molecular weight of about 1200 and 0.39 grams of 2,5-dimercapto-1,3,4-thiadiazole (0.0026 mol). The mixture was mixed well and heat was applied to a reaction temperature of 240° F. Then 6.29 grams of elemental sulfur (0.196 mol) was added. After one hour, the reaction temperature is increased to 280° F. and held for 16-24 hours. This reaction takes place under a nitrogen blanket. The resulting alkyl phenol free polymeric thiophosphate had the following analysis:

% Phosphorous 7.8
% Sulfur      7.6
Color, APHA   60
% Nonylphenol 0

DP-6T (Triisodecyl Phosphite) Doverphos 6

To a three-neck 250 mL flask equipped with a mechanical stirrer and purged with nitrogen was added 75.83 grams of a Triisodecyl phosphite, with a molecular weight of about 500 and 0.39 grams of 2,5-dimercapto-1,3,4-thiadiazole (0.0026 mol). The mixture was mixed well and heat was applied to a reaction temperature of 240° F. Then 4.87 of elemental sulfur (0.152 mol) was added. After one hour, the reaction temperature is increased to 280° F. and held for 16-24 hours. This reaction takes place under a nitrogen blanket. The resulting alkyl phenol free thiophosphate had the following analysis:

% Phosphorous 6.2
% Sulfur      6.0
Color, APHA   60
% Nonylphenol 0

Testing Methodology

Four Ball Wear: This test is used for evaluating friction-reducing and anti-wear fluids. Testing involves 3 stationary steel balls secured in a steel cup and a 4^th steel ball lowered to make contact with the 3 stationary balls. The fluid to be tested is poured into the cup. The 4^th ball is the only ball that spins. Typical rpm for the ball is 1200 rpm. The single ball spins in contact with the 3 stationary balls at a constant load of 40 kg. Typical run time is 1 hour. The wear on the lower 3 balls is measured and reported in mm. The fluid to produce the smallest wear scars has the best performance.

Parameter     Setting
Load (kg)     40
Temperature   Ambient
Time (min)    60
Dilution Rate 5%
Speed (rpm)   1,200

Wear Scar (Mm)

Ball	Example 1	Example 2	Example 3	Example 4	Example 5
1	0.91	0.39	0.52	0.52	0.57
2	0.91	0.39	0.52	0.52	0.55
3	0.86	0.39	0.52	0.52	0.55
Avg. mm	0.89	0.39	0.52	0.52	0.55

Test results clearly show that the alkylphenol free polymeric polyphosphites give excellent results, better than the commercial trisnonylphenyl thiophosphate with excellent color. And there are no alkylphenols in the final products.

Timken Testing: Timken testing was carried out by adding weight to a lever applying pressure to a block that is in contact with a wheel. The bottom portion of the wheel is submersed in the fluid to be tested. As the wheel spins, the lubricant is carried to the interface of the block and wheel. A one pound weight is added to the lever every minute until a maximum of 13 pounds has been added. The wear scar on the block is measured and reported in millimeters. See FIG. 1.

Wear Scar (Mm)

Example 1	Example 2	Example 3	Example 4	Example 5
2.34	2.08	2.08	2.24	2.60

Test results clearly show that the alkylphenol free polymeric polyphosphites give excellent results, better than the commercial trisnonylphenyl thiophosphate with excellent color. And there are no alkylphenols in the final products.

Examples II

The following formulae were prepared for various machine testing:

Oil Based Formulae

		Conc. %	Methyl
Additive	Functionality	By Weight	Ester Added
Paroil 152	Chlorinated Paraffin	5	7
Mayfree 133	Phosphate Amide	2.6	4.4
Doverphos 253	Di-oleyl Hydrogen	2.6	7
	Phosphite
Doverphos 53	Tri-lauryl Phosphite	2.6	7
Doverphos 50	Phosphite	2.6	7
Complex Ester 5%	Ester	5	0
Complex Ester 10%	Ester	10	0
Complex Ester 25%	Ester	25	0
Alkylphenol Free	Phosphite	2.6	7
Polymeric Phosphite A
Alkylphenol Free	Phosphite	2.6	7
Polymeric Phosphite B
Base 10SE	Sulfurized Ester	5	2
Alkylphenol Free	Phos & Sulfur	5	7
Polymeric
Thiophosphate A
Alkylphenol Free	Phos & Sulfur	5	7
Polymeric
Thiophosphate B
ZDDP	Phos, Sulfur & Zinc	2.6	7

Water Based Formulae

The water based formulae were prepared using a commercial semi-synthetic. The additive was added to either the Super Concentrate (SC) prior to dilution of the semi-synthetic with water, or to the concentrate after 50% dilution of the semi-synthetic with water. After the 50% dilution with water, all testing was conducted with the semi-synthetic diluted in water at 5%.

		% Added	% Added to	Final
	Additive	to S.C.	Concentrate	Conc. %
	Paroil 152	5	0	5
	Mayfree 133	0	2.6	5
	Doverphos 253	0	2.6	5
	Doverphos 53	0	2.6	5
	Dovephos 50	0	2.6	5
	Complex Ester 5%	0	5	5
	Alkylphenol Free	0	2.6	5
	Polymeric
	Phosphite A
	Alkylphenol Free	0	2.6	5
	Polymeric
	Phosphite B

Testing Methodology

Oil Based Testing:

Four Ball Wear: This test is used for evaluating friction-reducing and anti-wear fluids. Testing involves 3 stationary steel balls secured in a steel cup and a 4^th steel ball lowered to make contact with the 3 stationary balls. The fluid to be tested is poured into the cup. The 4th ball is the only ball that spins. Typical rpm for the ball is 1200 rpm. The single ball spins in contact with the 3 stationary balls at a constant load of 40 kg. Typical run time is 1 hour. The wear on the lower 3 balls is measured and reported in mm. The fluid to produce the smallest wear scars has the best performance.

Parameter   Setting
Load (kg)   40
Temperature Ambient
Time (min)  60
Speed (rpm) 1,200

Wear Scar (Mm)

Additive                   Average Wear, mm
Paroil 152, Std.           0.99
Doverphos 53               0.41
ZDDP                       0.45
Base 10SE                  0.52
Doverphos 253              0.54
Mayfree 133                0.61
Alkylphenol Free Polymeric 0.36
Phosphite A
Alkylphenol Free Polymeric 0.49
Phosphite B
Doverphos 50               0.46
Alkylphenol Free Polymeric 0.36
Thiophosphate A
Alkylphenol Free Polymeric 0.39
Thiophosphate B
Polymeric Ester-5%         0.66
Polymeric Ester-10%        0.65
Polymeric Ester-25%        0.53

Vertical Drawbead: Vertical Drawbead is a machine used to determine a fluids ability to form a piece of metal. Vertical Drawbead works by applying pressure to a coated metal strip. The formulae to be tested is applied to a 24 inch metal strip which is raised between two dye. The dyes apply 500 psi of pressure to the bottom of the strip. The coated strip is pulled between the two dyes. The amount of force needed to pull the strip between the dyes, is plotted by an X-Y plotter and the force is calculated from this curve. In all cases, higher percent efficiency refers to the performance of the fluid being better.

In this test, all formulae were evaluated on 1018 Steel and 316 Stainless Steel.

316 Stainless Steel

Additive                   % Efficiency
Paroil 152, Std.           100.0
Doverphos 53               95.1
ZDDP                       103.8
Base 10SE                  81.0
Doverphos 253              77.3
Mayfree 133                102.2
Alkylphenol Free Polymeric 70.3
Phosphite A
Alkylphenol Free Polymeric 46.4
Phosphite B
Doverphos 50               103.8
Alkylphenol Free Polymeric 114.2
Thiophosphate A
Alkylphenol Free Polymeric 119.0
Thiophosphate B
Polymeric Ester-5%         112.5
Polymeric Ester-10%        116.8
Polymeric Ester-25%        147.6

1018 Steel

Additive                   % Efficiency
Paroil 152, Std.           100.0
Doverphos 53               109.4
ZDDP                       103.8
Base 10SE                  103.3
Doverphos 253              105.4
Mayfree 133                97.1
Alkylphenol Free Polymeric 103.5
Phosphite A
Alkylphenol Free Polymeric 102.3
Phosphite B
Doverphos 50               111.6
Alkylphenol Free Polymeric 107.0
Thiophosphate A
Alkylphenol Free Polymeric 102.3
Thiophosphate B
Polymeric Ester-5%         111.9
Polymeric Ester-10%        113.1
Polymeric Ester-25%        129.5

Microtap Tap and Torque Testing: Microtap testing is one method used to determine a fluids ability to remove metal. A metal bar with predrilled holes is fastened to a vice. The tap and the metal bar are coated in the fluid to be tested. The tap rotates to tap out the pre-drilled hole. The force needed to tap the hole is measured by a computer and is reported as torque in newton centimeters. In all cases, higher percent efficiency refers to the performance of the fluid being better.

In this test, all formulae were evaluated on 1018 Steel.

1018 Steel

Additive                   % Efficiency
Paroil 152, Std.           100.0
Doverphos 53               101.7
ZDDP                       101.1
Base 10SE                  100.5
Doverphos 253              101.1
Mayfree 133                103.8
Alkylphenol Free Polymeric 103.1
Phosphite A
Alkylphenol Free Polymeric 102.9
Phosphite B
Doverphos 50               103.8
Alkylphenol Free Polymeric 103.5
Thiophosphate A
Alkylphenol Free Polymeric 104.3
Thiophosphate B
Polymeric Ester-5%         105.2
Polymeric Ester-10%        104.0
Polymeric Ester-25%        106.9

Falex Pin and Vee Block Testing: Falex Pin and Vee Block measures the fluids ability to perform in more severe operations, such as cold heading, but can also apply to grinding operations. A pin is fastened using a brass shear pin. Two Vee blocks are clamped onto the pin. The pin and vee blocks are submerged in the fluid to be tested. The load applied on the pin from the vee blocks begins at 250 pounds. The load is increased automatically by a ratcheting arm as the pin spins between the two vee blocks. The torque generated by the load on the pin is read at 250 pound load and is recorded every 250 pounds until a final load of 4500 pounds is reached or a failure occurs. A failure implies the pin or shear pin has broken. See FIGS. 2 and 3.

Water Based Testing:

Microtap Tap and Torque Testing: Microtap testing is one method used to determine a fluids ability to remove metal. A metal bar with predrilled holes is fastened to a vice. The tap and the metal bar are coated in the fluid to be tested. The tap rotates to tap out the predrilled hole. The force needed to tap the hole is measured by a computer and is reported as torque in newton centimeters. In all cases, higher percent efficiency refers to the performance of the fluid being better.

In this test, all formulae were evaluated on 1018 Steel and 316 Stainless Steel.

316 Stainless Steel

Additive                   % Efficiency
Paroil 152, Std.           100.0
Doverphos 53               108.6
Doverphos 253              112.0
Mayfree 133                117.6
Alkylphenol Free Polymeric 109.4
Phosphite A
Alkylphenol Free Polymeric 112.1
Phosphite B
Doverphos 50               109.4
Polymeric Ester-5%         107.6

1018 Steel

Additive                   % Efficiency
Paroil 152, Std.           100.0
Doverphos 53               102.4
Doverphos 253              101.1
Mayfree 133                101.9
Alkylphenol Free Polymeric 100.9
Phosphite A
Alkylphenol Free Polymeric 100.2
Phosphite B
Doverphos 50               100.0
Polymeric Ester-5%         99.3

Falex Pin and Vee Block Testing: Falex Pin and Vee Block measures the fluids ability to perform in more severe operations, such as cold heading, but can also apply to grinding operations. A pin is fastened using a brass shear pin. Two Vee blocks are clamped onto the pin. The pin and vee blocks are submerged in the fluid to be tested. The load applied on the pin from the vee blocks begins at 250 pounds. The load is increased automatically by a ratcheting arm as the pin spins between the two vee blocks. The torque generated by the load on the pin is read at 250 pound load and is recorded every 250 pounds until a final load of 4500 pounds is reached or a failure occurs. A failure implies the pin or shear pin has broken. See FIGS. 4 and 5.

Claims

1. A method comprising the step: using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

2. The method of claim 1, wherein each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

3. The method of claim 1, wherein the compound has a weight ranging from 1000 to 30000 Daltons.

4. The method of claim 1, wherein the compound has a weight ranging from 400 to 30000 Daltons.

5. The method of claim 1, wherein the compound has a weight ranging from 500 to 30000 Daltons.

6. A method comprising the step: using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

7. The method of claim 6, wherein each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

8. The method of claim 6, wherein the compound has a weight ranging from 1000 to 30000 Daltons.

9. The method of claim 6, wherein the compound has a weight ranging from 400 to 30000 Daltons.

10. The method of claim 6, wherein the compound has a weight ranging from 500 to 30000 Daltons.

11. A method comprising the step: using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

12. The method of claim 11, wherein each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

13. The method of claim 11, wherein the compound has a weight ranging from 1000 to 30000 Daltons.

14. The method of claim 11, wherein the compound has a weight ranging from 400 to 30000 Daltons.

15. The method of claim 11, wherein the compound has a weight ranging from 500 to 30000 Daltons.

16. A method comprising the step: using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

17. The method of claim 16, wherein each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

18. The method of claim 16, wherein the compound has a weight ranging from 1000 to 30000 Daltons.

19. The method of claim 16, wherein the compound has a weight ranging from 400 to 30000 Daltons.

20. The method of claim 16, wherein the compound has a weight ranging from 500 to 30000 Daltons.

21. A method comprising the step: using a copolymer compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

22. The method of claim 21, wherein each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

23. The method of claim 21, wherein the compound has a weight ranging from 1000 to 30000 Daltons.

24. The method of claim 21, wherein the compound has a weight ranging from 400 to 30000 Daltons.

25. The method of claim 21, wherein the compound has a weight ranging from 500 to 30000 Daltons.

26. A method comprising the step: using a compound as an additive for: gear oil, grease, engine oil, combustion-engine lubricant, automatic transmission fluid, two-cycle engine lubricant, marine-engine lubricant, or anti-wear agent, the compound having the structure:

27. The method of claim 26, wherein each Y is an independently selected ethyl, propyl, cyclohexane dimethanol, or caprylactone moiety.

28. The method of claim 26, wherein the compound has a weight ranging from 1000 to 30000 Daltons.

29. The method of claim 26, wherein the compound has a weight ranging from 400 to 30000 Daltons.

30. The method of claim 26, wherein the compound has a weight ranging from 500 to 30000 Daltons.

31. The method of claim 21, wherein each Z is independently selected from the group consisting of S, H, and O.