U.S. patent application number 10/084835 was filed with the patent office on 2003-05-29 for method and composition for using organic, plant-derived, oil-extracted materials in gasolines for reduced emissions.
Invention is credited to Jordan, Frederick L..
Application Number | 20030097783 10/084835 |
Document ID | / |
Family ID | 23063315 |
Filed Date | 2003-05-29 |
United States Patent
Application |
20030097783 |
Kind Code |
A1 |
Jordan, Frederick L. |
May 29, 2003 |
Method and composition for using organic, plant-derived,
oil-extracted materials in gasolines for reduced emissions
Abstract
A gasoline is provided that includes a plant oil extract,
.beta.-carotene, and jojoba oil. The gasoline exhibits reduced
emissions of undesired components during combustion of the fuel. A
method for preparing the gasoline is also provided.
Inventors: |
Jordan, Frederick L.; (Santa
Ana, CA) |
Correspondence
Address: |
KNOBBE MARTENS OLSON & BEAR LLP
2040 MAIN STREET
FOURTEENTH FLOOR
IRVINE
CA
91614
US
|
Family ID: |
23063315 |
Appl. No.: |
10/084835 |
Filed: |
February 26, 2002 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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60278011 |
Mar 22, 2001 |
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Current U.S.
Class: |
44/307 ; 44/300;
44/401; 44/449; 44/451; 44/459 |
Current CPC
Class: |
C10L 1/1852 20130101;
C10L 1/19 20130101; C10L 1/00 20130101; C10L 1/306 20130101; C10L
1/1832 20130101; C10L 1/1802 20130101; C10L 1/1824 20130101; C10L
9/10 20130101; C10L 1/191 20130101; C10L 1/326 20130101; C10L
1/1608 20130101; C10L 1/301 20130101; C10L 1/14 20130101; C10L
1/231 20130101; C10L 1/1857 20130101; C10L 10/02 20130101 |
Class at
Publication: |
44/307 ; 44/401;
44/451; 44/449; 44/300; 44/459 |
International
Class: |
C10L 001/18; C10L
001/16 |
Claims
What is claimed is:
1. A gasoline, the gasoline comprising a base fuel and an additive
for reducing a pollutant emission, the additive comprising: a plant
oil extract; an antioxidant; and a thermal stabilizer.
2. The gasoline of claim 1, wherein the plant oil extract comprises
an oil extract of a plant of the Leguminosae family.
3. The gasoline of claim 1, wherein the plant oil extract is
selected from the group consisting of oil extract of vetch and oil
extract of barley.
4. The gasoline of claim 1, wherein the plant oil extract comprises
chlorophyll.
5. The gasoline of claim 1, wherein the antioxidant comprises
.beta.-carotene.
6. The gasoline of claim 1, wherein the thermal stabilizer
comprises jojoba oil.
7. The gasoline of claim 1, wherein the thermal stabilizer
comprises an ester of a C20-C22 straight chain monounsaturated
carboxylic acid.
8. The gasoline of claim 1, wherein the plant oil extract comprises
oil extract of vetch, wherein the antioxidant comprises
.beta.-carotene, and wherein the thermal stabilizer comprises
jojoba oil.
9. The gasoline of claim 1, further comprising a diluent.
10. The gasoline of claim 9, wherein the diluent is selected from
the group consisting of toluene, gasoline, diesel fuel, jet fuel,
and mixtures thereof.
11. The gasoline of claim 1, further comprising an oxygenate.
12. The gasoline of claim 11, wherein the oxygenate is selected
from the group consisting of methanol, ethanol, methyl tertiary
butyl ether, ethyl tertiary butyl ether, and tertiary amyl methyl
ether, and mixtures thereof.
13. The gasoline of claim 1, further comprising at least one
additional additive selected from the group consisting of octane
improvers, detergents, corrosion inhibitors, metal deactivators,
ignition accelerators, dispersants, anti-knock additives,
anti-run-on additives, anti-pre-ignition additives, anti-misfire
additives, antiwear additives, antioxidants, demulsifiers, carrier
fluids, solvents, fuel economy additives, emission reduction
additives, lubricity improvers, and mixtures thereof.
14. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
from about 50:1 to about 0.5:1, wherein a ratio of grams of oil
extract of vetch to milliliters jojoba oil in the gasoline is from
about 10:1 to about 0.5:1, and wherein a ratio of milliliters
jojoba oil to grams of .beta.-carotene in the gasoline is from
about 10:1 to about 0.5:1.
15. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
from about 24.2:1 to about 1.2:1, wherein a ratio of grams of oil
extract of vetch to milliliters jojoba oil in the gasoline is from
about 4.0:1 to about 1:1, and wherein a ratio of milliliters jojoba
oil to grams of .beta.-carotene in the gasoline is from about 6.0:1
to about 1.3:1.
16. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
from about 24.2:1 to about 7.3:1, wherein a ratio of grams of oil
extract of vetch to milliliters jojoba oil in the gasoline is from
about 4.0:1 to about 2.9:1, and wherein a ratio of milliliters
jojoba oil to grams of .beta.-carotene in the gasoline is from
about 6.0:1 to about 2.5:1.
17. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
about 24.2:1, wherein a ratio of grams of oil extract of vetch to
milliliters jojoba oil in the gasoline is about 4.0:1, and wherein
a ratio of milliliters jojoba oil to grams of .beta.-carotene in
the gasoline is about 6.0:1.
18. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
about 7.3:1, wherein a ratio of grams of oil extract of vetch to
milliliters jojoba oil in the gasoline is about 2.9:1, and wherein
a ratio of milliliters jojoba oil to grams of .beta.-carotene in
the gasoline is about 2.5:1.
19. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
about 21.8:1, wherein a ratio of grams of oil extract of vetch to
milliliters jojoba oil in the gasoline is about 4.0:1, and wherein
a ratio of milliliters jojoba oil to grams of .beta.-carotene in
the gasoline is about 5.5:1.
20. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
from about 4.8:1 to about 1.2:1, wherein a ratio of grams of oil
extract of vetch to milliliters jojoba oil in the gasoline is from
about 2.4:1 to about 1.0:1, and wherein a ratio of milliliters
jojoba oil to grams of .beta.-carotene in the gasoline is from
about 2.0:1 to about 1.3:1.
21. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
about 4.8:1, wherein a ratio of grams of oil extract of vetch to
milliliters jojoba oil in the gasoline is about 2.4:1, and wherein
a ratio of milliliters jojoba oil to grams of .beta.-carotene in
the gasoline is about 2.0:1.
22. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
about 1.2:1, wherein a ratio of grams of oil extract of vetch to
milliliters jojoba oil in the gasoline is about 1.0:1, and wherein
a ratio of milliliters jojoba oil to grams of .beta.-carotene in
the gasoline is about 1.3:1.
23. The gasoline of claim 8, wherein a ratio of grams of plant oil
extract of vetch to grams of .beta.-carotene in the gasoline is
about 3.5:1, wherein a ratio of grams of oil extract of vetch to
milliliters jojoba oil in the gasoline is about 2.0:1, and wherein
a ratio of milliliters jojoba oil to grams of .beta.-carotene in
the gasoline is about 1.7:1.
24. The gasoline of claim 8, comprising from about 0.001 ml to
about 0.02 ml jojoba oil per 3785 ml of gasoline, from about
0.00001 g to about 0.01 g of .beta.-carotene per 3785 ml of
gasoline, and from about 0.001 g to about 0.05 g oil extract of
vetch per 3785 ml of gasoline.
25. The gasoline of claim 8, comprising from about 0.0021 ml to
about 0.0095 ml jojoba oil per 3785 ml of gasoline, from about
0.00053 g to about 0.0053 g of .beta.-carotene per 3785 ml of
gasoline, and from about 0.0061 g to about 0.023 g oil extract of
vetch per 3785 ml of gasoline.
26. The gasoline of claim 8, comprising from about 0.0021 ml to
about 0.0095 ml jojoba oil per 3785 ml of gasoline, from about
0.00053 g to about 0.0053 g of .beta.-carotene per 3785 ml of
gasoline, and from about 0.0061 g to about 0.013 g oil extract of
vetch per 3785 ml of gasoline.
27. The gasoline of claim 8, comprising about 0.0032 ml jojoba oil
per 3785 ml of gasoline, about 0.00053 g of 3-carotene per 3785 ml
of gasoline, and about 0.013 g oil extract of vetch per 3785 ml of
gasoline.
28. The gasoline of claim 8, comprising about 0.0021 ml jojoba oil
per 3785 ml of gasoline, about 0.00085 g of .beta.-carotene per
3785 ml of gasoline, and about 0.0061 g oil extract of vetch per
3785 ml of gasoline.
29. The gasoline of claim 8, comprising about 0.0047 ml jojoba oil
per 3785 ml of gasoline, about 0.00085 g of .beta.-carotene per
3785 ml of gasoline, and about 0.018 g oil extract of vetch per
3785 ml of gasoline.
30. The gasoline of claim 8, comprising from about 0.0063 ml to
about 0.0095 ml jojoba oil per 3785 ml of gasoline, from about
0.0048 g to about 0.0053 g of .beta.-carotene per 3785 ml of
gasoline, and from about 0.0061 g to about 0.023 g oil extract of
vetch per 3785 ml of gasoline.
31. The gasoline of claim 8, comprising about 0.0095 ml jojoba oil
per 3785 ml of gasoline, about 0.0048 g of .beta.-carotene per 3785
ml of gasoline, and about 0.023 g oil extract of vetch per 3785 ml
of gasoline.
32. The gasoline of claim 8, comprising about 0.0063 ml jojoba oil
per 3785 ml of gasoline, about 0.0051 g of .beta.-carotene per 3785
ml of gasoline, and about 0.0061 g oil extract of vetch per 3785 ml
of gasoline.
33. The gasoline of claim 8, comprising about 0.0091 ml jojoba oil
per 3785 ml of gasoline, about 0.0053 g of .beta.-carotene per 3785
ml of gasoline, and about 0.018 g oil extract of vetch per 3785 ml
of gasoline.
34. The gasoline of claim 1, wherein the gasoline comprises a
reformulated gasoline.
35. The gasoline of claim 1, wherein the gasoline comprises CaRFG3
gasoline.
36. The gasoline of claim 1, wherein the gasoline comprises
aviation gasoline.
37. A method for producing a gasoline, the method comprising the
steps of: preparing a first additive by combining .beta.-carotene,
jojoba oil, and a diluent, the first additive comprising about 4 ml
jojoba oil and about 4 g .beta.-carotene per 3785 ml of the first
additive; preparing a second additive by combining a oil extract of
vetch, jojoba oil, and a diluent, the second additive comprising
about 4 ml jojoba oil and about 19.36 g oil extract of vetch per
3785 ml of the second additive; and adding the first additive and
the second additive to a base fuel to produce a gasoline, such that
the gasoline comprises from about 0.5 ml to about 5 ml of the first
additive per 3785 ml of gasoline and from about 1.2 ml to about 3.6
ml of the second additive per 3785 ml of gasolin.
38. A method for producing a gasoline, the method comprising the
steps of: preparing a first additive by combining .beta.-carotene,
jojoba oil, and a diluent, the first additive comprising about 32
ml jojoba oil and about 32 g .beta.-carotene per 3785 ml of the
first additive; preparing a second additive by combining a oil
extract of vetch, jojoba oil, and a diluent, the second additive
comprising about 32 ml jojoba oil and about 155 g oil extract of
vetch per 3785 ml of the second additive; and adding the first
additive and the second additive to a base fuel to produce a
gasoline, such that the gasoline comprises from about 0.0625 ml to
about 0.625 ml of the first additive per 3785 ml of gasoline and
from about 0.3125 ml to about 0.45 ml of the second additive per
3785 ml of gasoline.
39. A method for operating a vehicle equipped with a
gasoline-powered engine, the method comprising the step of:
combusting a gasoline in the engine such that a quantity of a
pollutant is produced, wherein the gasoline comprises a base fuel,
a plant oil extract, an antioxidant, and a thermal stabilizer, and
wherein the quantity of the pollutant produced by combustion of
3785 ml of the gasoline is less than a quantity of the pollutant
produced upon combustion of 3785 ml of the base fuel.
Description
RELATED APPLICATION
[0001] This application claims the benefit of U.S. Provisional
Application No. 60/278,011, filed Mar. 22, 2001.
FIELD OF THE INVENTION
[0002] A gasoline is provided that includes a plant oil extract,
.beta.-carotene, and jojoba oil. The gasoline exhibits reduced
emissions of undesired components during combustion of the fuel. A
method for preparing the gasoline is also provided.
BACKGROUND OF THE INVENTION
[0003] Hydrocarbon fuels typically contain a complex mixture of
hydrocarbons molecules containing various configurations of
hydrogen and carbon atoms. They may also contain various additives,
including detergents, anti-icing agents, emulsifiers, corrosion
inhibitors, dyes, deposit modifiers, and non-hydrocarbons such as
oxygenates.
[0004] When such hydrocarbon fuels are combusted, a variety of
pollutants are generated. These combustion products include ozone,
particulates, carbon monoxide, nitrogen dioxide, sulfur dioxide,
and lead. Both the U.S. Environmental Protection Agency (EPA) and
the California Air Resources Board (CARB) have adopted ambient air
quality standards directed to these pollutants. Both agencies have
also adopted specifications for lower-emission gasolines.
[0005] The Phase 2 California Reformulated Gasoline (CaRFG2)
regulations became operative in Mar. 1, 1996. Governor Davis signed
Executive Order D-5-99 on Mar. 25, 1999, which directs the
phase-out of methyl tertiary butyl ether (MTBE) in California's
gasoline by Dec. 31, 2002. The Phase 3 California Reformulated
Gasoline (CaRFG3) regulations were approved on Aug. 3, 2000, and
became operative on Sep. 2, 2000. The CaRFG2 and CaRFG3 standards
are presented in Table 1.
1TABLE 1 The California Reformulated Gasoline Phase 2 and Phase 3
Specifications Flat Limits Averaging Limits Cap Limits CaRFG CaRFG
CaRFG CaRFG CaRFG CaRFG CaRFG CaRFG CaRFG Property Phase 1 Phase 1
Phase 1 Phase 1 Phase 2 Phase 3 Phase 1 Phase 2 Phase 3 Reid n/a
7.0 7.0 or 6.9 7.8 n/a n/a n/a 7.0 6.4-7.2 Vapor Pressure (psi)
Sulfur n/a 40 20 151 30 15 n/a 80 60 Content 30 (wt. ppm) Benzene
n/a 1.0 0.8 1.7 0.8 0.7 n/a 1.2 1.1 Content (vol. %) Aromatics n/a
25 25 32 22 22 n/a 30 35 Content (vol. %) Olefins n/a 6.0 6.0 9.6
4.0 4.0 n/a 10.0 10.0 Content (vol. %) T50 n/a 210 213 212 200 203
n/a 220 220 (.degree. F.) T90 n/a 300 305 329 290 295 n/a 330 330
(.degree. F.) Oxygen n/a 1.8-2.2 1.8-2.2 n/a n/a n/a n/a 1.8-3.5
1.8-3.5 Content 0-3.5 0-3.5 (wt. %) MTBE n/a n/a Prohibited n/a n/a
n/a n/a n/a Prohibited and Other Oxygenates (other than ethanol)
n/a = not applicable
[0006] Considerable effort has been expended by the major oil
companies to formulate gasolines that comply with the EPA and CARB
standards. The most common approach to formulating compliant
gasolines involves adjusting refinery processes so as to produce a
gasoline base fuel meeting the specifications set forth above. Such
an approach suffers a number of drawbacks, including the high costs
involved in reconfiguring a refinery process, possible negative
effects on the quantity or quality of other refinery products, and
the inflexibility associated with having to produce a compliant
base gasoline.
SUMMARY OF THE INVENTION
[0007] Conventional refinery-based processes for producing
gasolines that comply with the EPA and CARB standards suffer a
number of drawbacks. A method of producing compliant gasolines that
does not suffer these drawbacks is therefore desirable. A fuel
additive is provided which may be combined with conventional
noncompliant gasolines so as to yield a gasoline that complies with
the EPA and CARB standards. Because an additive is used to produce
compliant gasolines, the equipment and product costs associated
with a refinery solution are avoided. The additive may also be
combined with other hydrocarbon fuels, such as diesel fuels, jet
fuels, two-cycle fuels, and coals, to reduce the emission of
pollutants during combustion of the fuel.
[0008] In a first embodiment, a gasoline is provided, the gasoline
including a base fuel and an additive for reducing a pollutant
emission, the additive including: a plant oil extract; an
antioxidant; and a thermal stabilizer.
[0009] In an aspect of the first embodiment, the plant oil extract
includes an oil extract of a plant of the Leguminosae family, or
oil extract of vetch or oil extract of barley, or chlorophyll.
[0010] In an aspect of the first embodiment, the the antioxidant
includes .beta.-carotene.
[0011] In an aspect of the first embodiment, the the thermal
stabilizer includes jojoba oil. The thermal stabilizer may include
an ester of a C20-C22 straight chain monounsaturated carboxylic
acid.
[0012] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, and the thermal stabilizer includes jojoba
oil.
[0013] In an aspect of the first embodiment, the gasoline further
includes a diluent, such as toluene, gasoline, diesel fuel, jet
fuel, and mixtures thereof.
[0014] In an aspect of the first embodiment, the gasoline further
includes an oxygenate, such as methanol, ethanol, methyl tertiary
butyl ether, ethyl tertiary butyl ether, and tertiary amyl methyl
ether, and mixtures thereof.
[0015] In an aspect of the first embodiment, the gasoline further
includes at least one additional additive selected from the group
consisting of octane improvers, detergents, corrosion inhibitors,
metal deactivators, ignition accelerators, dispersants, anti-knock
additives, anti-run-on additives, anti-pre-ignition additives,
anti-misfire additives, antiwear additives, antioxidants,
demulsifiers, carrier fluids, solvents, fuel economy additives,
emission reduction additives, lubricity improvers, and mixtures
thereof.
[0016] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is from about 50:1 to about 0.5:1,
a ratio of grams of oil extract of vetch to milliliters jojoba oil
in the gasoline is from about 10:1 to about 0.5:1, and a ratio of
milliliters jojoba oil to grams of .beta.-carotene in the gasoline
is from about 10:1 to about 0.5:1.
[0017] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is from about 24.2:1 to about
1.2:1, a ratio of grams of oil extract of vetch to milliliters
jojoba oil in the gasoline is from about 4.0:1 to about 1:1, and a
ratio of milliliters jojoba oil to grams of .beta.-carotene in the
gasoline is from about 6.0:1 to about 1.3:1.
[0018] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is from about 24.2:1 to about
7.3:1, a ratio of grams of oil extract of vetch to milliliters
jojoba oil in the gasoline is from about 4.0:1 to about 2.9:1, and
a ratio of milliliters jojoba oil to grams of .beta.-carotene in
the gasoline is from about 6.0:1 to about 2.5:1.
[0019] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is about 24.2:1, a ratio of grams
of oil extract of vetch to milliliters jojoba oil in the gasoline
is about 4.0:1, and a ratio of milliliters jojoba oil to grams of
.beta.-carotene in the gasoline is about 6.0:1.
[0020] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is about 7.3:1, a ratio of grams of
oil extract of vetch to milliliters jojoba oil in the gasoline is
about 2.9:1, and a ratio of milliliters jojoba oil to grams of
.beta.-carotene in the gasoline is about 2.5:1.
[0021] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is about 21.8:1, a ratio of grams
of oil extract of vetch to milliliters jojoba oil in the gasoline
is about 4.0:1, and a ratio of milliliters jojoba oil to grams of
.beta.-carotene in the gasoline is about 5.5:1.
[0022] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is from about 4.8:1 to about 1.2:1,
a ratio of grams of oil extract of vetch to milliliters jojoba oil
in the gasoline is from about 2.4:1 to about 1.0:1, and a ratio of
milliliters jojoba oil to grams of .beta.-carotene in the gasoline
is from about 2.0:1 to about 1.3:1.
[0023] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is about 4.8:1, a ratio of grams of
oil extract of vetch to milliliters jojoba oil in the gasoline is
about 2.4:1, and a ratio of milliliters jojoba oil to grams of
.beta.-carotene in the gasoline is about 2.0:1.
[0024] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is about 1.2:1, a ratio of grams of
oil extract of vetch to milliliters jojoba oil in the gasoline is
about 1.0:1, and a ratio of milliliters jojoba oil to grams of
.beta.-carotene in the gasoline is about 1.3:1.
[0025] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and a
ratio of grams of plant oil extract of vetch to grams of
.beta.-carotene in the gasoline is about 3.5:1, a ratio of grams of
oil extract of vetch to milliliters jojoba oil in the gasoline is
about 2.0:1, and a ratio of milliliters jojoba oil to grams of
.beta.-carotene in the gasoline is about 1.7:1.
[0026] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including from about 0.001 ml to about 0.02 ml jojoba
oil per 3785 ml of gasoline, from about 0.00001 g to about 0.01 g
of .beta.-carotene per 3785 ml of gasoline, and from about 0.001 g
to about 0.05 g oil extract of vetch per 3785 ml of gasoline.
[0027] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including from about 0.0021 ml to about 0.0095 ml
jojoba oil per 3785 ml of gasoline, from about 0.00053 g to about
0.0053 g of .beta.-carotene per 3785 ml of gasoline, and from about
0.0061 g to about 0.023 g oil extract of vetch per 3785 ml of
gasoline.
[0028] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including from about 0.0021 ml to about 0.0095 ml
jojoba oil per 3785 ml of gasoline, from about 0.00053 g to about
0.0053 g of .beta.-carotene per 3785 ml of gasoline, and from about
0.0061 g to about 0.013 g oil extract of vetch per 3785 ml of
gasoline.
[0029] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including about 0.0032 ml jojoba oil per 3785 ml of
gasoline, about 0.00053 g of .beta.-carotene per 3785 ml of
gasoline, and about 0.013 g oil extract of vetch per 3785 ml of
gasoline.
[0030] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including about 0.0021 ml jojoba oil per 3785 ml of
gasoline, about 0.00085 g of .beta.-carotene per 3785 ml of
gasoline, and about 0.0061 g oil extract of vetch per 3785 ml of
gasoline.
[0031] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including about 0.0047 ml jojoba oil per 3785 ml of
gasoline, about 0.00085 g of .beta.-carotene per 3785 ml of
gasoline, and about 0.018 g oil extract of vetch per 3785 ml of
gasoline.
[0032] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including from about 0.0063 ml to about 0.0095 ml
jojoba oil per 3785 ml of gasoline, from about 0.0048 g to about
0.0053 g of .beta.-carotene per 3785 ml of gasoline, and from about
0.0061 g to about 0.023 g oil extract of vetch per 3785 ml of
gasoline.
[0033] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including about 0.0095 ml jojoba oil per 3785 ml of
gasoline, about 0.0048 g of .beta.-carotene per 3785 ml of
gasoline, and about 0.023 g oil extract of vetch per 3785 ml of
gasoline.
[0034] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes
.beta.-carotene, the thermal stabilizer includes jojoba oil, and
the gasoline including about 0.0063 ml jojoba oil per 3785 ml of
gasoline, about 0.0051 g of .beta.-carotene per 3785 ml of
gasoline, and about 0.0061 g oil extract of vetch per 3785 ml of
gasoline.
[0035] In an aspect of the first embodiment, the plant oil extract
includes oil extract of vetch, the antioxidant includes i-carotene,
the thermal stabilizer includes jojoba oil, and the gasoline
including about 0.0091 ml jojoba oil per 3785 ml of gasoline, about
0.0053 g of .beta.-carotene per 3785 ml of gasoline, and about
0.018 g oil extract of vetch per 3785 ml of gasoline.
[0036] In an aspect of the first embodiment, the gasoline includes
a reformulated gasoline.
[0037] In an aspect of the first embodiment, the gasoline includes
CaRFG3 gasoline.
[0038] In an aspect of the first embodiment, the gasoline includes
aviation gasoline.
[0039] In a second embodiment, a method for producing a gasoline is
provided, the method including the steps of: preparing a first
additive by combining .beta.-carotene, jojoba oil, and a diluent,
the first additive including about 4 ml jojoba oil and about 4 g
.beta.-carotene per 3785 ml of the first additive; preparing a
second additive by combining a oil extract of vetch, jojoba oil,
and a diluent, the second additive including about 4 ml jojoba oil
and about 19.36 g oil extract of vetch per 3785 ml of the second
additive; and adding the first additive and the second additive to
a base fuel to produce a gasoline, such that the gasoline includes
from about 0.5 ml to about 5 ml of the first additive per 3785 ml
of gasoline and from about 1.2 ml to about 3.6 ml of the second
additive per 3785 ml of gasolin.
[0040] In a third embodiment, a method for producing a gasoline is
provided, the method including the steps of: preparing a first
additive by combining .beta.-carotene, jojoba oil, and a diluent,
the first additive including about 32 ml jojoba oil and about 32 g
.beta.-carotene per 3785 ml of the first additive; preparing a
second additive by combining a oil extract of vetch, jojoba oil,
and a diluent, the second additive including about 32 ml jojoba oil
and about 155 g oil extract of vetch per 3785 ml of the second
additive; and adding the first additive and the second additive to
a base fuel to produce a gasoline, such that the gasoline includes
from about 0.0625 ml to about 0.625 ml of the first additive per
3785 ml of gasoline and from about 0.3125 ml to about 0.45 ml of
the second additive per 3785 ml of gasoline.
[0041] In a fourth embodiment, a method for operating a vehicle
equipped with a gasoline-powered engine is provided, the method
including the step of: combusting a gasoline in the engine such
that a quantity of a pollutant is produced, wherein the gasoline
includes a base fuel, a plant oil extract, an antioxidant, and a
thermal stabilizer, and wherein the quantity of the pollutant
produced by combustion of 3785 ml of the gasoline is less than a
quantity of the pollutant produced upon combustion of 3785 ml of
the base fuel.
BRIEF DESCRIPTION OF THE DRAWINGS
[0042] FIG. 1 illustrates a Metered Injection Pumping System for
additizing resid fuels.
[0043] FIG. 2 provides a hypothetical temperature versus time curve
for the piston cycle of a gasoline-powered engine operating on
untreated fuel and fuel treated with the OR-1 additive.
[0044] FIG. 3 provides a schematic illustrating the layout of the
Vehicle Emissions Testing Laboratory located in Section 27,
Selangor Darul Ehsan, Shah Alam, Malaysia.
[0045] FIG. 4 provides a diagram illustrating the European
Emissions Standard ECE R15-04 plus EUDC Emissions Test Cycle.
[0046] FIG. 5 provides NO.sub.x emissions as a function of odometer
miles for a Ford Taurus.
[0047] FIG. 6 provides CO emissions as a function of odometer miles
for a Ford Taurus.
[0048] FIG. 7 provides NMHC emissions as a function of odometer
miles for a Ford Taurus.
[0049] FIG. 8 provides CO.sub.2 emissions as a function of odometer
miles for a Ford Taurus.
[0050] FIG. 9 provides mpg fuel economy as a function of odometer
miles for a Ford Taurus.
[0051] FIG. 10 provides NO.sub.x emissions as a function of
odometer miles for a Honda Accord.
[0052] FIG. 11 provides CO emissions as a function of odometer
miles for a Honda Accord.
[0053] FIG. 12 provides NMHC emissions as a function of odometer
miles for a Honda Accord.
[0054] FIG. 13 provides CO.sub.2 emissions as a function of
odometer miles for a Honda Accord.
[0055] FIG. 14 provides mpg fuel economy as a function of odometer
miles for a Honda Accord.
[0056] FIG. 15 provides a Shewhart Control Plot for NO.sub.x in the
Honda Accord with the first three baselines excluded.
[0057] FIG. 16 provides a Shewhart Control Plot for CO in the Honda
Accord with the first three baselines excluded.
[0058] FIG. 17 provides a Shewhart Control Plot for NMHC in the
Honda Accord with the first three baselines excluded.
[0059] FIG. 18 provides a Shewhart Control Plot for CO.sub.2 in the
Honda Accord with the first three baselines excluded.
[0060] FIG. 19 provides a Shewhart Control Plot for mpg fuel
economy in the Honda Accord with the first three baselines
excluded.
[0061] FIG. 20 is a photograph of a piston top of a General Motors
Electro Motor Division 645-12, 2000 horsepower, 900 rpm two-cycle
engine after 1300 hours of operation on OR-2 diesel fuel.
[0062] FIG. 21 is a photograph of the head General Motors Electro
Motor Division 645-12, 2000 horsepower, 900 rpm two-cycle engine
1300 hours of operation on OR-2 diesel fuel.
[0063] FIG. 22 is a photograph of the #2 piston top of a
Caterpillar 930 loader before operation on OR-2 additized diesel
fuel.
[0064] FIG. 23 is a photograph of the #2 piston top of a
Caterpillar 930 loader after 7385 hours of operation on OR-2
additized diesel fuel.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Introduction
[0065] The following description and examples illustrate preferred
embodiments of the present invention in detail. Those of skill in
the art will recognize that there are numerous variations and
modifications of this invention that are encompassed by its scope.
Accordingly, the description of preferred embodiments should not be
deemed to limit the scope of the present invention.
Emissions Reduction Additive Formulation
[0066] The emissions reduction additive formulation contains three
components: an oil extract from vetch, .beta.-carotene, and jojoba
oil.
Oil Extract from Vetch
[0067] In a preferred embodiment, one of the components of the
formulation is a plant oil extracted from, e.g., vetch, hops,
barley, or alfalfa. The term "plant oil extract" as used herein, is
a broad term and is used in its ordinary sense, including, without
limitation, those components present in the plant material which
are soluble in n-hexane. Chlorophyll may be used as a substitute
for, or in addition to, all or a portion of the oil extract. The
hydrophobic oil extract contains chlorophyll. Chlorophyll is the
green pigment in plants that accomplishes photosynthesis, the
process in which carbon dioxide and water combine to form glucose
and oxygen. The hydrophobic oil extract typically also contains
many other compounds, including, but not limited to,
organometallics, antioxidants, oils, lipids thermal stabilizers or
the starting materials for these types of products, and
approximately 300 other compounds primarily consisting of low to
high molecular weight antioxidants.
[0068] While the oil extract from vetch is preferred in many
embodiments, in other embodiments it may be desirable to
substitute, in whole or in part, another plant oil extract,
including, but not limited to, alfalfa, hops oil extract, fescue
oil extract, barley oil extract, green clover oil extract, wheat
oil extract, extract of the green portions of grains, green food
materials oil extract, green hedges or green leaves or green grass
oil extract, any flowers containing green portions, the leafy or
green portion of a plant of any member of the legume family,
chlorophyll or chlorophyll containing extracts, or combinations or
mixtures thereof. Suitable legumes include legume selected from the
group consisting of lima bean, kidney bean, pinto bean, red bean,
soy bean, great northern bean, lentil, navy bean, black turtle
bean, pea, garbanzo bean, and black eye pea. Suitable grains
include fescue, clover, wheat, oats, barley, rye, sorghum, flax,
tritcale, rice, corn, spelt, millet, amaranth, buckwheat, quinoa,
kamut, and teff.
[0069] Especially preferred plant oil extracts are those derived
from plants that are members of the Fabaceae (Leguminosae) plant
family, commonly referred to as the pulse family, and also as the
pea or legume family. The Leguminosae family includes over 700
genera and 17,000 species, including shrubs, trees, and herbs. The
family is divided into three subfamilies: divided into three
subfamilies: Mimosoideae, which are mainly tropical trees and
shrubs; Caesalpinioideae, which include tropical and sub-tropical
shrubs; and Papilioniodeae which includes peas and beans. A common
feature of most members of the Leguminosae family is the presence
of root nodules containing nitrogen-fixing Rhizobium bacteria. Many
members of the Leguminosae family also accumulate high levels of
vegetable oils in their seeds. The Leguminosae family includes the
lead-plant, hog peanut, wild bean, Canadian milk vetch, indigo,
soybean, pale vetchling, marsh vetchling, veiny pea, round-headed
bush clover, perennial lupine, hop clover, alfalfa, white sweet
clover, yellow sweet clover, white prairie-clover, purple
prairie-clover, common locust, small wild bean, red clover, white
clover, narrow-leaved vetch, hairy vetch, garden pea, chick pea,
string green, kidney bean, mung bean, lima bean, broad bean,
lentil, peanut or groundnut, and the cowpea, to name but a few.
[0070] The most preferred form of oil-extracted material consists
of a material having a paste or mud-like consistency after
extraction, namely, a solid or semi-solid, rather than a liquid,
after extraction. Such pastes typically contain a higher
concentration of Chlorophyll A to Chlorophyll B in the extract. The
color of such a material is generally a deep black-green with a
some degree of fluorescence throughout the material. Such a
material can be recovered from many or all the plant sources
enumerated for the Leguminosae family. While such a form is
generally preferred for most embodiments, in certain other
embodiments a liquid or some other form may be preferred.
[0071] The oil extract may be obtained using extraction methods
well known to those of skill in the art. Solvent extraction methods
are generally preferred. Any suitable extraction solvent may be
used which is capable of separating the oil and oil-soluble
fractions from the plant material. Nonpolar extraction solvents are
generally preferred. The solvent may include a single solvent, or a
mixture of two or more solvents. Suitable solvents include, but are
not limited to, cyclic, straight chain, and branched-chain alkanes
containing from about 5 or fewer to 12 or more carbon atoms.
Specific examples of acyclic alkane extractants include pentane,
hexane, heptane, octane, nonane, decane, mixed hexanes, mixed
heptanes, mixed octanes, isooctane, and the like. Examples of the
cycloalkane extractants include cyclopentane, cyclohexane,
cycloheptane, cyclooctane, methylcyclohexane, and the like. Alkenes
such as hexenes, heptenes, octenes, nonenes, and decenes are also
suitable for use, as are aromatic hydrocarbons such as benzene,
toluene, and xylene. Halogenated hydrocarbons such as
chlorobenzene, dichlorobenzene, trichlorobenzene, methylene
chloride, chloroform, carbon tetrachloride, perchloroethylene,
trichloroethylene, trichloroethane, and trichlorotrifluoroethane
may also be used. Generally preferred solvents are C6 to C12
alkanes, particularly n-hexane.
[0072] Hexane extraction is the most commonly used technique for
extracting oil from seeds. It is a highly efficient extraction
method that extracts virtually all oil-soluble fractions in the
plant material. In a typical hexane extraction, the plant material
is comminuted. Grasses and leafy plants may be chopped into small
pieces. Seed are typically ground or flaked. The plant material is
typically exposed to hexane at an elevated temperature. The hexane,
a highly flammable, colorless, volatile solvent that dissolves out
the oil, typically leaves only a few weight percent of the oil in
the residual plant material. The oil/solvent mixture may be heated
to 212.degree. F., the temperature at which hexane flashes off, and
is then distilled to remove all traces of hexane. Alternatively,
hexane may be removed by evaporation at reduced pressure. The
resulting oil extract is suitable for use in the formulations of
preferred embodiments.
[0073] Plant oils extracts for use in edible items or cosmetics
typically undergo additional processing steps to remove impurities
that may affect the appearance, shelf life, taste, and the like, to
yield a refined oil. These impurities include may include
phospholipids, mucilaginous gums, free fatty acids, color pigments
and fine plant particles. Different methods are used to remove
these by-products including water precipitation or precipitation
with aqueous solutions of organic acids. Color compounds are
typically removed by bleaching, wherein the oil is typically passed
through an adsorbent such as diatomaceous clay. Deodorization may
also be conducted, which typically involves the use of steam
distillation. Such additional processing steps are generally
unnecessary. However, oils subjected to such treatments may be
suitable for use in the formulations of preferred embodiments.
[0074] Other preferred extraction processes include, but are not
limited to, supercritical fluid extraction, typically with carbon
dioxide. Other gases, such as helium, argon, xenon, and nitrogen
may also be suitable for use as solvents in supercritical fluid
extraction methods.
[0075] Any other suitable method may be used to obtain the desired
oil extract fractions, including, but not limited to, mechanical
pressing. Mechanical pressing, also known as expeller pressing,
removes oil through the use of continuously driven screws that
crush the seed or other oil-bearing material into a pulp from which
the oil is expressed. Friction created in the process can generate
temperatures between about 50.degree. C. and 90.degree. C., or
external heat may be applied. Cold pressing generally refers to
mechanical pressing conducted at a temperature of 40.degree. C. or
less with no external heat applied.
[0076] The yield of oil extract that may be obtained from a plant
material may depend upon any number of factors, but primarily upon
the oil content of the plant material. For example, a typical oil
content of vetch (hexane extraction, dry basis) is approximately 4
to 5 wt. %, while that for barley is approximately 6 to 7.5 wt. %,
and that for alfalfa is approximately 2 to 4.2 wt. %.
.beta.-Carotene
[0077] .beta.-Carotene is another component of the formulations of
preferred embodiments. The .beta.-carotene may be added to the base
formulation as a separate component, or may be present or naturally
occurring in one of the other base components, such as, for
example, one of the components of the oil extract from vetch.
.beta.-Carotene is a high molecular weight antioxidant. In plants,
it functions as a scavenger of oxygen radicals and protects
chlorophyll from oxidation. While not wishing to be limited to any
particular mechanism, it is believed that the .beta.-carotene in
the formulations of preferred embodiments may scavenge oxygen
radicals in the combustion process or may act as an oxygen
solubilizer or oxygen getter for the available oxygen that is
present in the air/fuel stream for combustion.
[0078] The .beta.-carotene may be natural or synthetic. In a
preferred embodiment, the .beta.-carotene is provided in a form
equivalent to vitamin A having a purity of 1.6 million units of
vitamin A activity. Vitamin A of lesser purity may also be suitable
for use, provided that the amount used is adjusted to yield an
equivalent activity. For example, if the purity is 800,000 units of
vitamin A activity, the amount used is doubled to yield the desired
activity.
[0079] While .beta.-carotene is preferred in many embodiments, in
other embodiments it may be desirable to substitute, in whole or in
part, another component for .beta.-carotene, including, but not
limited to, .alpha.-carotene, or additional carotenoids from algae
xeaxabthin, crypotoxanthin, lycopene, lutein, broccoli concentrate,
spinach concentrate, tomato concentrate, kale concentrate, cabbage
concentrate, brussels sprouts concentrate and phospholipids, green
tea extract, milk thistle extract, curcumin extract, quercetin,
bromelain, cranberry and cranberry powder extract, pineapple
extract, pineapple leaves extract, rosemary extract, grapeseed
extract, ginkgo biloba extract, polyphenols, flavonoids, ginger
root extract, hawthorn berry extract, bilberry extract, butylated
hydroxytoluene (BHT), oil extract of marigolds, any and all oil
extracts of carrots, fruits, vegetables, flowers, grasses, natural
grains, leaves from trees, leaves from hedges, hay, any living
plant or tree, and combinations or mixtures thereof.
[0080] Vegetable carotenoids of guaranteed potency are particularly
preferred, including those containing lycopene, lutein,
.alpha.-carotene, other carotenoids from carrots or algae,
betatene, and natural carrot extract. While the vegetable
carotenoids are particularly preferred as substitutes for
.beta.-carotene or in combination with .beta.-carotene, other
substances with antioxidant properties may also be suitable for use
in the formulations of preferred embodiments, either as substitutes
for .beta.-carotene or additional components, including phenolic
antioxidants, amine antioxidants, sulfurized phenolic compounds,
organic phosphites, and the like, as enumerated elsewhere in this
application. Preferably, the antioxidant is oil soluble. If the
antioxidant is insoluble or only sparingly soluble in aqueous
solution, it may be desirable to use a surfactant to improve its
solubility.
Jojoba Oil
[0081] In a preferred embodiment, one of the components of the
formulation is jojoba oil. It is a liquid that has antioxidant
characteristics and is capable of withstanding very high
temperatures without losing its antioxidant abilities. Jojoba oil
is a liquid wax ester mixture extracted from ground or crushed
seeds from shrubs native to Arizona, California and northern
Mexico. The source of jojoba oil is the Simmondsia chinensis shrub,
commonly called the jojoba plant. It is a woody evergreen shrub
with thick, leathery, bluish-green leaves and dark brown, nutlike
fruit. Jojoba oil may be extracted from the fruit by conventional
pressing or solvent extraction methods. The oil is clear and golden
in color. Jojoba oil is composed almost completely of wax esters of
monounsaturated, straight-chain acids and alcohols with high
molecular weights (C16-C26). Jojoba oil is typically defined as a
liquid wax ester with the generic formula RCOOR", wherein RCO
represents oleic acid (C18), eicosanoic acid (C20) and/or erucic
acid (C22), and wherein --OR" represents eicosenyl alcohol (C20),
docosenyl alcohol (C22) and/or tetrasenyl alcohol (C24) moieties.
Pure esters or mixed esters having the formula RCOOR", wherein R is
a C20-C22 alk(en)yl group and wherein R" is a C20-C22 alk(en)yl
group, may be suitable substitutes, in part or in whole, for jojoba
oil. Acids and alcohols including monounsaturated straight-chain
alkenyl groups are most preferred.
[0082] While the jojoba oil is preferred in many embodiments, in
other embodiments it may be desirable to substitute, in whole or in
part, another component, including, but not limited to, oils that
are known for their thermal stability, such as, peanut oil,
cottonseed oil, rape seed oil, macadamia oil, avocado oil, palm
oil, palm kernel oil, castor oil, all other vegetable and nut oils,
all animal oils including mammal oils (e.g., whale oils) and fish
oils, and combinations and mixtures thereof. In preferred
embodiments, the oil may be alkoxylated, for example, methoxylated
or ethoxylated. Alkoxylation is preferably conducted on medium
chain oils, such as castor oil, macadamia nut oil, cottonseed oil,
and the like. Alkoxylation may offer benefits in that it may permit
coupling of oil/water mixtures in a fuel, resulting in a potential
reduction in nitrogen oxides and/or particulate matter emissions
upon combustion of the fuel.
[0083] In preferred embodiments, these other oils are substituted
for jojoba oil on a 1:1 volume ratio basis, in either a partial
substitution or complete substitution. In other embodiments it may
be preferred to substitute the other oil for jojoba oil at a volume
ration greater than or less than a 1:1 volume ratio. In a preferred
embodiment, cottonseed oil, either purified or merely extracted or
crushed from cottonseed, squalene, or squalane are substituted on a
1:1 volume ratio basis for a portion or an entire volume of jojoba
oil.
[0084] While not wishing to be limited to any particular mechanism,
it is believed that the jojoba oil acts to prevent or retard
pre-oxidation of the oil extract and/or .beta.-carotene components
of the formulation prior to combustion by imparting thermal
stability to the formulation. Jojoba oil generally reduces cetane
in fuels, so in formulations wherein a higher cetane number is
preferred, it is generally preferred to reduce the content of
jojoba oil in the formulation.
[0085] Although jojoba oil is preferred for used in many of the
formulations of the preferred embodiments, in certain formulations
it may be preferred to substitute one or more different thermal
stabilizers for jojoba oil, either in whole or in part. Suitable
thermal stabilizers as known in the art include liquid mixtures of
alkyl phenols, including 2-tert-butylphenol,
2,6-di-tert-butylphenol, 2-tert-butyl-4-n-butylphenol- ,
2,4,6-tri-tert-butylphenol, and 2,6-di-tert-butyl-4-n-butylphenol
which are suited for use as stabilizers for middle distillate fuels
( U.S. Pat. No. 5,076,814 and U.S. Pat. No. 5,024,775 to Hanlon, et
al.). Other commercially available hindered phenolic antioxidants
that also exhibit a thermal stability effect include
2,6-di-t-butyl-4-methylphenol; 2,6-di-t-butylphenol;
2,2'-methylene-bis(6-t-butyl-4-methylphenol); n-octadecyl
3-(3,5-di-t-butyl-4-hydroxyphenyl) propionate; 1,1,3
-tris(3-t-butyl-6-methyl-4-hydroxyphenyl) butane; pentaerythrityl
tetrakis[3-(3,5-di-t-butyl-4-hydroxyphenyl) propionate];
di-n-octadecyl(3,5-di-t-butyl-4-hydroxybenzyl)phosphonate;
2,4,6-tris(3,5-di-t-butyl-4-hydroxybenzyl) mesitylene; and
tris(3,5-di-t-butyl-4-hydroxybenzyl)isocyanurate (U.S. Pat. No.
4,007,157, U.S. Pat. No. 3,920,661).
[0086] Other thermal stabilizers include: pentaerythritol co-esters
derived from pentaerythritol, (3-alkyl-4-hydroxyphenyl)-alkanoic
acids and alkylthioalkanoic acids or lower alkyl esters of such
acids which are useful as stabilizers of organic material normally
susceptible to oxidative and/or thermal deterioration. (U.S. Pat.
No. 4,806,675 and U.S. Pat. No. 4,734,519 to Dunski, et al.); the
reaction product of malonic acid, dodecyl aldehyde and tallowamine
(U.S. Pat. No. 4,670,021 to Nelson, et al.); hindered phenyl
phosphites (U.S. Pat. No. 4,207,229 to Spivack); hindered
piperidine carboxylic acids and metal salts thereof (U.S. Pat. No.
4,191,829 and U.S. Pat. No. 4,191,682 to Ramey, et al.); acylated
derivatives of 2,6-dihydroxy-9-azabicyclo[3.3.1]nonane (U.S. Pat.
No. 4,000,113 to Stephen); bicyclic hindered amines (U.S. Pat. No.
3,991,012 to Ramey, et al.); sulfur containing derivatives of
dialkyl-4-hydroxyphenyltriazine (U.S. Pat. No. 3,941,745 to Dexter,
et al.); bicyclic hindered amino acids and metal salts thereof
(U.S. 4,051,102 to Ramey , et al.); trialkylsubstituted
hydroxybenzyl malonates (U.S. Pat. No. 4,081,475 to Spivack);
hindered piperidine carboxylic acids and metal salts thereof (U.S.
Pat. No. 4,089,842 to Ramey , et al.); pyrrolidine dicarboxylic
acids and esters (U.S. Pat. No. 4,093,586 to Stephen); metal salts
of N,N-disubstituted .beta.-alanines (U.S. Pat. No. 4,077,941 to
Stephen , et al.); hydrocarbyl thioalkylene phosphites (U.S. Pat.
No. 3,524,909); hydroxybenzyl thioalkylene phosphites ( U.S. Pat.
No. 3,655,833); and the like.
[0087] Certain compounds are capable of performing as both
antioxidants and as thermal stabilizers. Therefore, in certain
embodiments it may be preferred to prepare formulations containing
a hydrophobic plant oil extract in combination with a single
compound that provides both a thermal stability and antioxidant
effect, rather than two different compounds, one providing thermal
stability and the other antioxidant activity. Examples of compounds
known in the art as providing some degree of both oxidation
resistance and thermal stability include diphenylamines,
dinaphthylamines, and phenylnaphthylamines, either substituted or
unsubstituted, e.g., N,N'-diphenylphenylenediamine,
p-octyldiphenylamine, p,p-dioctyldiphenylamine,
N-phenyl-1-naphthylamine, N-phenyl-2-naphthylamine,
N-(p-dodecyl)phenyl-2-naphthylamine, di-1-naphthylamine, and
di-2naphthylamine; phenothazines such as N-alkylphenothiazines;
imino(bisbenzyl); and hindered phenols such as 6-(t-butyl)phenol,
2,6-di-(t-butyl)phenol, 4-methyl-2,6-di-(t-butyl) phenol,
4,4'-methylenebis(-2,6-di-(t-butyl)phenol), and the like.
[0088] Certain lubricating fluid base stocks are known in the art
to exhibit high thermal stability. Such base stocks may be capable
of imparting thermal stability to the formulations of preferred
embodiments, and as such may be substituted, in part or in whole,
for jojoba oil. Suitable base stocks include polyalphaolefins,
dibasic acid esters, polyol esters, alkylated aromatics,
polyalkylene glycols, and phosphate esters.
[0089] Polyalphaolefins are hydrocarbon polymers that contain no
sulfur, phosphorus, or metals. Polyalphaolefins have good thermal
stability, but are typically used in conjunction with a suitable
antioxidant. Dibasic acid esters also exhibit good thermal
stability, but are usually also used in combination with additives
for resistance to hydrolysis and oxidation.
[0090] Polyol esters include molecules containing two or more
alcohol moieties, such as trimethylolpropane, neopentylglycol, and
pentaerythritol esters. Synthetic polyol esters are the reaction
product of a fatty acid derived from either animal or plant sources
and a synthetic polyol. Polyol esters have excellent thermal
stability and may resist hydrolysis and oxidation better than other
base stocks. Naturally occurring triglycerides or vegetable oils
are in the same chemical family as polyol esters. However, polyol
esters tend to be more resistant to oxidation than such oils. The
oxidation instabilities normally associated with vegetable oils are
generally due to a high content of linoleic and linolenic fatty
acids. Moreover, the degree of unsaturation (or double bonds) in
the fatty acids in vegetable oils correlates with sensitivity to
oxidation, with a greater number of double bonds resulting in a
material more sensitive to and prone to rapid oxidation.
[0091] Trimethylolpropane esters may include mono, di, and tri
esters. Neopentyl glycol esters may include mono and di esters.
Pentaerythritol esters include mono, di, tri, and tetra esters.
Dipentaerythritol esters may include up to six ester moieties.
Preferred esters are typically of those of long chain monobasic
fatty acids. Esters of C20 or higher acids are preferred, e.g.,
gondoic acid, eicosadienoic acid, eicosatrienoic acid,
eicosatetraenoic acid, eicosapentanoic acid, arachidic acid,
arachidonic acid, behenic acid, erucic acid, docosapentanoic acid,
docosahexanoic acid, or ligniceric acid. However in certain
embodiments, esters of C18 or lower acids may be preferred, e.g.,
butyric acid, caproic acid, caprylic acid, capric acid, lauric
acid, myristoleic acid, myristic acid, pentadecanoic acid, palmitic
acid, palmitoleic acid, hexadecadienoic acid, hexadecatienoic acid,
hexadecatetraenoic acid, margaric acid, margroleic acid, stearic
acid, linoleic acid, octadecatetraenoic acid, vaccenic acid, or
linolenic acid. In certain embodiments, it may be preferred to
esterify the pentaerythritol with a mixture of different acids.
[0092] Alkylated aromatics are formed by the reaction of olefins or
alkyl halides with aromatic compounds, such as benzene. Thermal
stability is similar to that of polyalphaolefins, and additives are
typically used to provide oxidative stability. Polyalkylene glycols
are polymers of alkylene oxides exhibiting good thermal stability,
but are typically used in combination with additives to provide
oxidation resistance. Phosphate esters are synthesized from
phosphorus oxychloride and alcohols or phenols and also exhibit
good thermal stability.
[0093] In certain embodiments, it may be preferred to prepare
formulations containing jojoba oil in combination with other
vegetable oils. For example, it has been reported that crude
meadowfoam oil resists oxidative destruction nearly 18 times longer
than the most common vegetable oil, namely, soybean oil. Meadowfoam
oil may be added in small amounts to other oils, such as triolein
oil, jojoba oil, and castor oil, to improve their oxidative
stability. Crude meadowfoam oil stability could not be attributed
to common antioxidants. One possible explanation for the oxidative
stability of meadowfoam oil may be its unusual fatty acid
composition. The main fatty acid from meadowfoam oil is
5-eicosenoic acid, which was found to be nearly 5 times more stable
to oxidation than the most common fatty acid, oleic acid, and 16
times more stable than other monounsaturated fatty acids. See
"Oxidative Stability Index of Vegetable Oils in Binary Mixtures
with Meadowfoam Oil," Terry, et al., United States Department of
Agriculture, Agricultural Research Service, 1997.
Ratios of Components and Concentrations in Additized Fuel
[0094] In preferred embodiments, the three components of the base
formulation are present specified ratios. In determining the ratios
of the components, factors taken into consideration may include
elevation, base fuel purity, type of fuel (e.g., gasoline, diesel,
residual fuel, two-cycle fuel, and the like), sulfur content,
mercaptan content, olefin content, aromatic content and the engine
or device using the fuel (e.g., gasoline powered engine, diesel
engine, two-cycle engine, stationary boiler). For example, if a
gasoline or diesel fuel is of a lower grade, such as one that has a
high sulfur content (1 wt. % or more), a high olefin content (12
ppm or higher), or a high aromatics content (35 wt. % or higher) in
gasoline or diesel, the ratios may be adjusted to compensate by
providing additional oil extract and .beta.-carotene (or other
antioxidant).
[0095] In additive formulations and additized liquid or solid
hydrocarbon fuels of preferred embodiments, the ratio of grams of
oil extract of vetch to grams of .beta.-carotene in the additive is
generally from about 50:1 to about 1:0.05; typically from about
24:1 to about 1:0.1; preferably from about 22:1, 20:1, 15:1, 10:1
to about 1:0.2, 1:0.3, 1:0.4, 1:0.5, 1:0.6, 1:0.7, 1:0.8, or 1:0.9;
and more preferably from about 9:1, 8:1, 7.5:1, 7:1, 6.5:1, 6:1,
5.5:1, 5:1, 4.5:1, 4:1, 3.5:1, 3:1, 2.5:1, 2:1, to about 1:1,
1:1.1, 1:1.2, 1:1.3, 1:1.4, 1:1.5, 1:1.6, 1:1.7, 1:1.8, or 1:1.9.
The ratio of grams of oil extract of vetch to milliliters jojoba
oil in the additive is generally from about 12:1 to about 1:0.05;
typically from about 6:1 to about 1:0.2, 1:0.3, 1:0.4, 1:0.5,
1:0.6, 1:0.7, 1:0.8, or 1:0.9; and more preferably from about
5.5:1, 5:1, 4.5:1, 4:1, 3.5:1, 3:1, 2.5:1, 2:1, to about 1:1,
1:1.1, 1:1.2, 1:1.3, 1:1.4, 1:1.5, 1:1.6, 1:1.7, 1:1.8, or 1:1.9.
The ratio of milliliters jojoba oil to grams of .beta.-carotene in
the additive is generally from about 12:1 to about 1:0.5; typically
from about 6:1 to about 1:0.6, 1:0.7, 1:0.8, or 1:0.9; and more
preferably from about 5.5:1, 5:1, 4.5:1, 4:1, 3.5:1, 3:1, 2.5:1,
2:1, to about 1:1, 1:1.1, 1:1.2, 1:1.3, 1:1.4, 1:1.5, 1:1.6, 1:1.7,
1:1.8, or 1:1.9.
[0096] It is generally preferred that the ratios of each component
approach approximately 1:1:1, namely, that a balance point between
the raw materials in the formulation is reached, however the total
treat rate may be adjusted up or down depending upon various
factors as described above.
[0097] Different ratios of the components of the additive
formulation may be preferred for preparing additized gasoline for
different regions or altitudes. When the gasoline is for use in the
United States at altitudes below 762 meters, the ratio of grams of
oil extract of vetch to grams of .beta.-carotene in the additive is
preferably from about 24.2:1; the ratio of grams of oil extract of
vetch to milliliters jojoba oil in the additive is preferably from
about 4:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably from about 6:1.
[0098] When the gasoline is for use in the United States at
altitudes from 762 meters to 1524 meters, the ratio of grams of oil
extract of vetch to grams of .beta.-carotene in the additive is
preferably from about 7.3:1; the ratio of grams of oil extract of
vetch to milliliters jojoba oil in the additive is preferably from
about 2.9:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably from about 2.5:1.
[0099] When the gasoline is for use in the United States at
altitudes above 1524 meters, the ratio of grams of oil extract of
vetch to grams of .beta.-carotene in the additive is preferably
from about 21.8:1; the ratio of grams of oil extract of vetch to
milliliters jojoba oil in the additive is preferably from about
4:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably from about 5.5:1.
[0100] When the gasoline is for use in the Mexico at altitudes
below 762 meters, the ratio of grams of oil extract of vetch to
grams of .beta.-carotene in the additive is preferably from about
4.8:1; the ratio of grams of oil extract of vetch to milliliters
jojoba oil in the additive is preferably from about 2.4:1; and the
ratio of milliliters jojoba oil to grams of .beta.-carotene is
preferably from about 2:1.
[0101] When the gasoline is for use in the Mexico at altitudes from
762 meters to 1524 meters, the ratio of grams of oil extract of
vetch to grams of .beta.-carotene in the additive is preferably
from about 1.2:1; the ratio of grams of oil extract of vetch to
milliliters jojoba oil in the additive is preferably from about
1.0:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably from about 1.3:1.
[0102] When the gasoline is for use in the Mexico at altitudes
above 1524 meters, the ratio of grams of oil extract of vetch to
grams of .beta.-carotene in the additive is preferably from about
3.5:1; the ratio of grams of oil extract of vetch to milliliters
jojoba oil in the additive is preferably from about 2:1; and the
ratio of milliliters jojoba oil to grams of .beta.-carotene is
preferably from about 1.7:1.
[0103] Different ratios of the components of the additive
formulation may also be preferred for different regions and
altitudes when the additized fuel is diesel fuel. When the diesel
fuel is for use in the United States at altitudes below 762 meters,
the ratio of grams of oil extract of vetch to grams of
.beta.-carotene in the additive is preferably from about 8.1:1; the
ratio of grams of oil extract of vetch to milliliters jojoba oil in
the additive is preferably from about 3:1; and the ratio of
milliliters jojoba oil to grams of .beta.-carotene is preferably
from about 2.7:1.
[0104] When the diesel fuel is for use in the United States at
altitudes from 762 meters to 1524 meters, the ratio of grams of oil
extract of vetch to grams of .beta.-carotene in the additive is
preferably from about 6.1:1; the ratio of grams of oil extract of
vetch to milliliters jojoba oil in the additive is preferably from
about 2.7:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably from about 2.3:1.
[0105] When the diesel fuel is for use in the United States at
altitudes above 1524 meters, the ratio of grams of oil extract of
vetch to grams of .beta.-carotene in the additive is preferably
from about 4.8:1; the ratio of grams of oil extract of vetch to
milliliters jojoba oil in the additive is preferably from about
2.4:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably from about 2:1. Alternatively, the
ratios may be adjusted down to lower values, namely, a ratio of
grams of oil extract of vetch to grams of .beta.-carotene in the
additive of about 3.5:1; a ratio of grams of oil extract of vetch
to milliliters jojoba oil in the additive of about 2:1; and a ratio
of milliliters jojoba oil to grams of .beta.-carotene of about
1.7:1.
[0106] When the diesel fuel is for use in the Mexico at altitudes
below 762 meters, the ratio of grams of oil extract of vetch to
grams of .beta.-carotene in the additive is preferably from about
4.8:1; the ratio of grams of oil extract of vetch to milliliters
jojoba oil in the additive is preferably from about 2.4:1; and the
ratio of milliliters jojoba oil to grams of .beta.-carotene is
preferably from about 2:1.
[0107] When the diesel fuel is for use in the Mexico at altitudes
from 762 meters to 1524 meters, the ratio of grams of oil extract
of vetch to grams of .beta.-carotene in the additive is preferably
from about 6.1:1; the ratio of grams of oil extract of vetch to
milliliters jojoba oil in the additive is preferably from about
1.7:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably from about 2.3:1.
[0108] When the diesel fuel is for use in the Mexico at altitudes
above 1524 meters, the ratio of grams of oil extract of vetch to
grams of .beta.-carotene in the additive is preferably from about
4:1; the ratio of grams of oil extract of vetch to milliliters
jojoba oil in the additive is preferably from about 2.2:1; and the
ratio of milliliters jojoba oil to grams of .beta.-carotene is
preferably from about 1.8:1.
[0109] When the additive formulation is to be used in resid fuels,
e.g., in the United States, Mexico, or other regions of the world,
the ratio of grams of oil extract of vetch to grams of
.beta.-carotene in the additive is preferably from about 1:0.6; the
ratio of grams of oil extract of vetch to milliliters jojoba oil in
the additive is preferably from about 1:0.6; and the ratio of
milliliters jojoba oil to grams of .beta.-carotene is preferably
from about 1:1. It is generally preferred to use a greater
proportion of jojoba oil and .beta.-carotene and a smaller
proportion of oil extract of vetch present in resid formulations
than is preferred in gasoline and diesel fuel formulations. This is
because resid fuels are generally combusted at a higher air to fuel
ratio, generally resulting in higher combustion temperatures.
[0110] The additive formulation may also be used to prepare
two-cycle fuels with reduced emissions. In two-cycle fuels, a
reduced proportion of oil extract of vetch compared to jojoba oil
and .beta.-carotene is generally preferred. As a general trend, the
lower the proportion of oil extract of vetch, the lower the smoke
levels observed for the fuel. Alternatively, the concentration of
the opacity from a two-cycle engine is reduced as the amount of
.beta.-carotene is increased. The relative smoke levels observed
for selected ratios are as follows (oil extract of vetch:
.beta.-carotene/oil extract of vetch:jojoba oil/jojoba oil:
.beta.-carotene):
2.1/1.5/1.4>6.0/2.7/2.2>1.0/0.8/1.2>0.5/0.5/1.-
1>0.3/0.3/1.1>0.1/0.1/1.0. It is generally observed that
vetch extract, alfalfa extract, cottonseed oil, and chlorophyll
reduce nitrogen oxides in two-cycle fuels.
[0111] When the hydrocarbon fuel to be additized is coal, either in
solid form or as a suspension in water or another liquid, the ratio
of grams of oil extract of vetch to grams of .beta.-carotene in the
additive is preferably about 5:4; the ratio of grams of oil extract
of vetch to milliliters jojoba oil in the additive is preferably
about 2.5:1; and the ratio of milliliters jojoba oil to grams of
.beta.-carotene is preferably about 1:2.
Other Additives
[0112] The additive packages and formulated fuels compositions of
preferred embodiments may contain additives other than the ones
described above. These additives may include, but are not limited
to, one or more octane improvers, detergents, antioxidants,
demulsifiers, corrosion inhibitors and/or metal deactivators,
diluents, cold flow improvers, thermal stabilizers, and the like,
as described below.
[0113] Octane Improvers--Compounds of this type are useful for
providing combined benefits to gasoline-based fuels. These
compounds have the ability of effectively raising the octane
quality of the fuel. In addition, these compounds effectively
reduce undesirable tailpipe emissions from the engine. A class of
suitable octane improvers includes the cyclopentadienyl manganese
tricarbonyl compounds. Preferred are the cyclopentadienyl manganese
tricarbonyls that are liquid at room temperature such as
methylcyclopentadienyl manganese tricarbonyl, ethylcyclopentadienyl
manganese tricarbonyl, liquid mixtures of cyclopentadienyl
manganese tricarbonyl and methylcyclopentadienyl manganese
tricarbonyl, mixtures of methylcyclopentadienyl manganese
tricarbonyl and ethylcyclopentadienyl manganese tricarbonyl, and
the like. Preparation of such compounds is described in the
literature, for example, U.S. Pat. No. 2,818,417.
[0114] Cetane Improvers--If the fuel composition is a diesel fuel,
it may preferably contain a cetane improver or ignition
accelerator. The ignition accelerator is preferably an organic
nitrate different from and in addition to the nitrate or nitrate
source described above. Preferred organic nitrates are substituted
or unsubstituted alkyl or cycloalkyl nitrates having up to about 10
carbon atoms, preferably from 2 to 10 carbon atoms. The alkyl group
may be either linear or branched. Specific examples of nitrate
compounds suitable for use in preferred embodiments include, but
are not limited to the following: methyl nitrate, ethyl nitrate,
n-propyl nitrate, isopropyl nitrate, allyl nitrate, n-butyl
nitrate, isobutyl nitrate, sec-butyl nitrate, tert-butyl nitrate,
n-amyl nitrate, isoamyl nitrate, 2-amyl nitrate, 3-amyl nitrate,
tert-amyl nitrate, n-hexyl nitrate, 2-ethylhexyl nitrate, n-heptyl
nitrate, sec-heptyl nitrate, n-octyl nitrate, sec-octyl nitrate,
n-nonyl nitrate, n-decyl nitrate, n-dodecyl nitrate,
cyclopentylnitrate, cyclohexylnitrate, methylcyclohexyl nitrate,
isopropylcyclohexyl nitrate, and the esters of alkoxy substituted
aliphatic alcohols, such as 1-methoxypropyl-2-nitrate,
1-ethoxpropyl-2 nitrate, 1-isopropoxy-butyl nitrate, 1-ethoxylbutyl
nitrate and the like. Preferred alkyl nitrates are ethyl nitrate,
propyl nitrate, amyl nitrates, and hexyl nitrates. Other preferred
alkyl nitrates are mixtures of primary amyl nitrates or primary
hexyl nitrates. By primary is meant that the nitrate functional
group is attached to a carbon atom which is attached to two
hydrogen atoms. Examples of primary hexyl nitrates include n-hexyl
nitrate, 2-ethylhexyl nitrate, 4-methyl-n-pentyl nitrate, and the
like. Preparation of the nitrate esters may be accomplished by any
of the commonly used methods: such as, for example, esterification
of the appropriate alcohol, or reaction of a suitable alkyl halide
with silver nitrate. Another additive suitable for use in improving
cetane and/or reducing particulate emissions is di-t-butyl
peroxide.
[0115] Ignition Accelerators--Conventional ignition accelerators
may also be used in the preferred embodiments, such as hydrogen
peroxide, benzoyl peroxide, di-tert-butyl peroxide, and the like.
Moreover, certain inorganic and organic chlorides and bromides,
such as, for example, aluminum chloride, ethyl chloride or bromide
may find use in the preferred embodiments as primers when used in
combination with the other ignition accelerators.
[0116] Detergent Additives--Carburetor deposits may form in the
throttle body and plate, idle air circuit, and in the metering
orifices and jets. These deposits are a combination of contaminants
from dust and engine exhaust, held together by gums formed from
unsaturated hydrocarbons in the fuel. They can alter the air/fuel
ratio, cause rough idling, increased fuel consumption, and
increased exhaust emissions. Carburetor detergents can prevent
deposits from forming and remove deposits already formed.
Detergents used for this application are amines in the 20-60 ppm
dosage range.
[0117] Fuel injectors are very sensitive to deposits that can
reduce fuel flow and alter the injector spray pattern. These
deposits can make vehicles difficult to start, cause severe
driveability problems, and increase fuel consumption and exhaust
emissions. Fuel injector deposits are formed at higher temperatures
than carburetor deposits and are therefore more difficult to deal
with. The amines used for carburetor deposits are somewhat
effective but are typically used at roughly the 100 ppm dosage
level. At this level, the amine detergent can actually cause the
formation of inlet manifold and valve deposits. Polymeric
dispersants with higher thermal stability than the amine detergents
have been used to overcome this problem. These are used at dosages
in the range of 20 to 600 ppm. These same additives are also
effective for inlet manifold and valve deposit control. Inlet
manifold and valve deposits have the same effect on driveability,
fuel consumption, and exhaust emissions as carburetor and engine
deposits. The effect of detergent and dispersant additives on
engines with existing deposits may require several tanks of
gasoline, especially if the additives are used at a low dosage
rate.
[0118] Combustion chamber deposits can cause an increase in the
octane number requirement for vehicles as they accumulate miles.
These deposits accumulate in the end-gas zone and injection port
area. They are thermal insulators and so can become very hot during
engine operation. The metallic surfaces conduct heat away and
remain relatively cool. The hot deposits can cause pre-ignition and
misfire leading to the need for a higher-octane fuel.
Polyetheramine and other proprietary additives are known to reduce
the magnitude of combustion chamber deposits. Reduction in the
amount of combustion chamber deposits has been shown to reduce
NO.sub.x emissions.
[0119] Any of a number of different types of suitable gasoline
detergent additives can be included in both diesel and gasoline
fuel compositions of various embodiments. These detergents include
succinimide detergent/dispersants, long-chain aliphatic polyamines,
long-chain Mannich bases, and carbamate detergents. Desirable
succinimide detergent/dispersants for use in gasolines are prepared
by a process that includes reacting an ethylene polyamine such as
diethylene triamine or triethylene tetramine with at least one
acyclic hydrocarbyl substituted succinic acylating agent. The
substituent of such acylating agent is characterized by containing
an average of about 50 to about 100 (preferably about 50 to about
90 and more preferably about 64 to about 80) carbon atoms.
Additionally, the acylating agent has an acid number in the range
of about 0.7 to about 1.3 (for example, in the range of 0.9 to 1.3,
or in the range of 0.7 to 1.1), more preferably in the range of 0.8
to 1.0 or in the range of 1.0 to 1.2, and most preferably about
0.9. The detergent/dispersant contains in its molecular structure
in chemically combined form an average of from about 1.5 to about
2.2 (preferably from 1.7 to 1.9 or from 1.9 to 2.1, more preferably
from 1.8 to 2.0, and most preferably about 1.8) moles of the
acylating agent per mole of the polyamine. The polyamine can be a
pure compound or a technical grade of ethylene polyamines that
typically are composed of linear, branched and cyclic species.
[0120] The acyclic hydrocarbyl substituent of the
detergent/dispersant is preferably an alkyl or alkenyl group having
the requisite number of carbon atoms as specified above. Alkenyl
substituents derived from poly-olefin homopolymers or copolymers of
appropriate molecular weight (for example, propene homopolymers,
butene homopolymers, C.sub.3 and C.sub.4 olefin copolymers, and the
like) are suitable. Most preferably, the substituent is a
polyisobutenyl group formed from polyisobutene having a number
average molecular weight (as determined by gel permeation
chromatography) in the range of 700 to 1200, preferably 900 to
1100, most preferably 940 to 1000. The established manufacturers of
such polymeric materials are able to adequately identify the number
average molecular weights of their own polymeric materials. Thus in
the usual case the nominal number average molecular weight given by
the manufacturer of the material can be relied upon with
considerable confidence.
[0121] Acyclic hydrocarbyl-substituted succinic acid acylating
agents and methods for their preparation and use in the formation
of succinimide are well known to those skilled in the art and are
extensively reported in the literature. See, for example, U.S. Pat.
No. 3,018,247.
[0122] Use of fuel-soluble long chain aliphatic polyamines as
induction cleanliness additives in distillate fuels is described,
for example, in U.S. Pat. No. 3,438,757.
[0123] Use in gasoline of fuel-soluble Marnich base additives
formed from a long chain alkyl phenol, formaldehyde (or a
formaldehyde precursor thereof), and a polyamine to control
induction system deposit formation in internal combustion engines
is described, for example, in U.S. Pat. No. 4,231,759.
[0124] Carbamate fuel detergents are compositions which contain
polyether and amine groups joined by a carbamate linkage. Typical
compounds of this type are described in U.S. Pat. No. 4,270,930. A
preferred material of this type is commercially available from
Chevron Oronite Company LLC of Houston, Tex. as OGA-480.TM.
additive.
[0125] Driveability Additives--These include anti-knock,
anti-run-on, anti-pre-ignition, and anti-misfire additives that
directly effect the combustion process. Anti-knock additives
include lead alkyls that are no longer used in the United States.
These and other metallic anti-knock additives are typically used at
dosages of roughly 0.2 g metal/liter of fuel (or about 0.1 wt % or
1000 ppm). A typical octane number enhancement at this dosage level
is 3 units for both Research Octane Number (RON) and Motor Octane
Number (MON). A number of organic compounds are also known to have
anti-knock activity. These include aromatic amines, alcohols, and
ethers that can be employed at dosages in the 1000 ppm range. These
additives work by transferring hydrogen to quench reactive
radicals. Oxygenates such as methanol and MTBE also increase octane
number but these are used at such high dosages that they are not
really additives but blend components. Pre-ignition is generally
caused by the presence of combustion chamber deposits and is
treated using combustion chamber detergents and by raising octane
number.
[0126] Antiwear Agents--The gasoline and diesel fuel compositions
of various embodiments advantageously contain one or more antiwear
agents. Preferred antiwear agents include long chain primary amines
incorporating an alkyl or alkenyl radical having 8 to 50 carbon
atoms. The amine to be employed may be a single amine or may
consist of mixtures of such amines. Examples of long chain primary
amines which can be used in the preferred embodiments are
2-ethylhexyl amine, n-octyl amine, n-decyl amine, dodecyl amine,
oleyl amine, linolylamine, stearyl amine, eicosyl amine, triacontyl
amine, pentacontyl amine and the like. A particularly effective
amine is oleyl amine obtainable from Akzo Nobel Surface Chemistry
LLC of Chicago, Ill. under the name ARMEEN.RTM. O or ARMEEN.RTM.
OD. Other suitable amines which are generally mixtures of aliphatic
amines include ARMEEN.RTM. T and ARMEEN.RTM. TD, the distilled form
of ARMEEN.RTM. T which contains a mixture of 0-2% of tetradecyl
amine, 24% to 30% of hexadecyl amine, 25% to 28% of octadecyl amine
and 45% to 46% of octadecenyl amine. ARMEEN.RTM. T and ARMEEN.RTM.
TD are derived from tallow fatty acids. Lauryl amine is also
suitable, as is ARMEEN.RTM. 12D obtainable from the supplier
indicated above. This product is about 0-2% of decylamine, 90% to
95% dodecylamine, 0-3% of tetradecylamine and 0-1% of
octadecenylamine. Amines of the types indicated to be useful are
well known in the art and may be prepared from fatty acids by
converting the acid or mixture of acids to its ammonium soap,
converting the soap to the corresponding amide by means of heat,
further converting the amide to the corresponding nitrile and
hydrogenating the nitrile to produce the amine. In addition to the
various amines described, the mixture of amines derived from soya
fatty acids also falls within the class of amines above described
and is suitable for use according to this invention. It is noted
that all of the amines described above as being useful are straight
chain, aliphatic primary amines. Those amines having 16 to 18
carbon atoms per molecule and being saturated or unsaturated are
particularly preferred.
[0127] Other preferred antiwear agents include dimerized
unsaturated fatty acids, preferably dimers of a comparatively long
chain fatty acid, for example one containing from 8 to 30 carbon
atoms, and may be pure, or substantially pure, dimers.
Alternatively, and preferably, the material sold commercially and
known as "dimer acid" may be used. This latter material is prepared
by dimerizing unsaturated fatty acid and consists of a mixture of
monomer, dimer and trimer of the acid. A particularly preferred
dimer acid is the dimer of linoleic acid.
[0128] Antioxidants--Various compounds known for use as oxidation
inhibitors can be utilized in fuel formulations of various
embodiments. These include phenolic antioxidants, amine
antioxidants, sulfurized phenolic compounds, and organic
phosphites, among others. For best results, the antioxidant
includes predominately or entirely either (1) a hindered phenol
antioxidant such as 2,6-di-tert-butylphenol,
4-methyl-2,6-di-tert-butylphenol, 2,4-dimethyl-6-tert-butylphenol,
4,4'-methylenebis(2,6-di-tert-butylphenol), and mixed methylene
bridged polyalkyl phenols, or (2) an aromatic amine antioxidant
such as the cycloalkyl-di-lower alkyl amines, and
phenylenediamines, or a combination of one or more such phenolic
antioxidants with one or more such amine antioxidants. Particularly
preferred are combinations of tertiary butyl phenols, such as
2,6-di-tert-butylphenol, 2,4,6-tri-tert-butylphenol and
o-tert-butylphenol. Also useful are N,N'-di-lower-alkyl
phenylenediamines, such as N,N'-di-sec-butyl-p-phenylenediamine,
and its analogs, as well as combinations of such phenylenediamines
and such tertiary butyl phenols.
[0129] Demulsifiers--Demulsifiers are molecules that aid the
separation of oil from water usually at very low concentrations.
They prevent formation of a water and oil mixture. A wide variety
of demulsifiers are available for use in the fuel formulations of
various embodiments, including, for example, organic sulfonates,
polyoxyalkylene glycols, oxyalkylated phenolic resins, and like
materials. Particularly preferred are mixtures of alkylaryl
sulfonates, polyoxyalkylene glycols and oxyalkylated alkylphenolic
resins, such as are available commercially from Baker Petrolite
Corporation of Sugar Land, Tex. under the TOLAD.RTM. trademark.
Other known demulsifiers can also be used.
[0130] Corrosion Inhibitors--A variety of corrosion inhibitors are
available for use in the fuel formulations of various embodiments.
Use can be made of dimer and trimer acids, such as are produced
from tall oil fatty acids, oleic acid, linoleic acid, or the like.
Products of this type are currently available from various
commercial sources, such as, for example, the dimer and trimer
acids sold under the EMPOL.RTM. trademark by Cognis Corporation of
Cincinnati, Ohio. Other useful types of corrosion inhibitors are
the alkenyl succinic acid and alkenyl succinic anhydride corrosion
inhibitors such as, for example, tetrapropenylsuccinic acid,
tetrapropenylsuccinic anhydride, tetradecenylsuccinic acid,
tetradecenylsuccinic anhydride, hexadecenylsuccinic acid,
hexadecenylsuccinic anhydride, and the like. Also useful are the
half esters of alkenyl succinic acids having 8 to 24 carbon atoms
in the alkenyl group with alcohols such as the polyglycols.
[0131] Also useful are the aminosuccinic acids or derivatives.
Preferably a dialkyl ester of an aminosuccinic acid is used
containing an alkyl group containing 15-20 carbon atoms or an acyl
group which is derived from a saturated or unsaturated carboxylic
acid containing 2-10 carbon atoms. Most preferred is a dialkylester
of an aminosuccinic acid.
[0132] Metal Deactivators--If desired, the fuel compositions may
contain a conventional type of metal deactivator of the type having
the ability to form complexes with heavy metals such as copper and
the like. Typically, the metal deactivators used are gasoline
soluble N,N'-disalicylidene- 1,2-alkanediamines or
N,N'-disalicylidene-1,2-cycloalkanediamines, or mixtures thereof.
Examples include N,N'-disalicylidene-1,2-ethanediamine,
N,N'-disalicylidene-1,2-propanediamine,
N,N'-disalicylidene-1,2-cyclo-hex- anediamine, and
N,N"-disalicylidene-N'-methyl-dipropylene-triamine.
[0133] The various additives that can be included in the diesel and
gasoline compositions of this invention are used in conventional
amounts. The amounts used in any particular case are sufficient to
provide the desired functional property to the fuel composition,
and such amounts are well known to those skilled in the art.
[0134] Thermal Stabilizers--Thermal stabilizers such as Octel
Starreon high temperature fuel oil stabilizer FOA-81.TM. for
gasoline, jet, and diesel fuel, or other such additives may also be
added to the fuel formulation.
[0135] Carrier fluids--Substances suitable for use as carrier
fluids include, but are not limited to, mineral oils, vegetable
oils, animal oils, and synthetic oils. Suitable mineral oils may be
primarily paraffinic, naphthenic, or aromatic in composition.
Animal oils include tallow and lard. Vegetable oils may include,
but are not limited to, rapeseed oil, soybean oil, peanut oil, corn
oil, sunflower oil, cottonseed oil, coconut oil, olive oil, wheat
germ oil, flaxseed oil, almond oil, safflower oil, castor oil, and
the like. Synthetic oils may include, but are not limited to, alkyl
benzenes, polybutylenes, polyisobutylenes, polyalphaolefins, polyol
esters, monoesters, diesters (adipates, sebacates, dodecanedioates,
phthalates, dimerates), and triesters.
[0136] Solvents--Solvents suitable for use in conjunction with the
formulations of preferred embodiments are miscible and compatible
with one or more components of the formulation. Preferred solvents
include the aromatic solvents, such as benzene, toluene, o-xylene,
m-xylene, p-xylene, and the like, as well as nonpolar solvents such
as cyclohexanes, hexanes, heptanes, octanes, nonanes, and the like.
Suitable solvents may also include the fuel to be additized, e.g.,
gasoline, Diesel 1, Diesel 2, and the like. Depending upon the
material to be solvated, other liquids may also be suitable for use
as solvents, such as oxygenates, carrier fluids, or even additives
as enumerated herein.
[0137] Oxygenates--Oxygenates are added to gasoline to improve
octane number and to reduce emissions of CO. These include various
alcohols and ethers that are typically blended with gasoline to
produce an oxygen content of up to about 10 volume percent. The CO
emissions benefit appears to be a function of fuel oxygen level and
not of oxygenate chemical structure. Because oxygenates have a
lower heating value than gasoline, volumetric fuel economy (miles
per gallon) is lower for fuels containing these components.
However, at typical blend levels the effect is so small that only
very precise measurements can detect it. Oxygenates are not known
to effect emissions of NO.sub.x or hydrocarbon.
[0138] In certain embodiments, it may be preferred to add one or
more oxygenates to the fuel. Oxygenates are hydrocarbons that
contain one or more oxygen atoms. The primary oxygenates are
alcohols and ethers, including: methanol, fuel ethanol, methyl
tertiary butyl ether (MTBE), ethyl tertiary butyl ether (ETBE), and
tertiary amyl methyl ether (TAME).
Additive Concentrates
[0139] The emission control/fuel economy additive package can be
added to the base fuel directly. Alternatively, the additive
formulation may be provided in the form of an additive package that
may be used to prepare an additized fuel. Optionally, various
additives described above may also be present in the
concentrate.
Additive Effects on Emissions and Fuel Economy
[0140] Gasoline additives can clearly have an effect on emissions
and fuel economy at dosages as low as 20 to 60 ppm. Additives that
remove existing fuel system or combustion chamber deposits have an
increasing effect over time and, upon removal of the additive from
the fuel, performance should slowly deteriorate back to the
baseline level. Driveability additives have an immediate effect and
are used at roughly 1000 ppm. The effect of oxygenates is also
immediate but blend levels are much higher than for the other
additive classes.
Base Fuels
Gasolines
[0141] The gasolines utilized in the practice of various
embodiments can be traditional blends or mixtures of hydrocarbons
in the gasoline boiling range, or they can contain oxygenated
blending components such as alcohols and/or ethers having suitable
boiling temperatures and appropriate fuel solubility, such as
methanol, ethanol, methyl tert-butyl ether (MTBE), ethyl tert-butyl
ether (ETBE), tert-amyl methyl ether (TAME), and mixed
oxygen-containing products formed by "oxygenating" gasolines and/or
olefinic hydrocarbons falling in the gasoline boiling range. Thus
various embodiments involve the use of gasolines, including the
so-called reformulated gasolines which are designed to satisfy
various governmental regulations concerning composition of the base
fuel itself, components used in the fuel, performance criteria,
toxicological considerations and/or environmental considerations.
The amounts of oxygenated components, detergents, antioxidants,
demulsifiers, and the like that are used in the fuels can thus be
varied to satisfy any applicable government regulations.
[0142] Aviation gasoline is especially for aviation piston engines,
with an octane number suited to the engine, a freezing point of
-60.degree. C., and a distillation range usually within the limits
of 30.degree. C. and 180.degree. C.
[0143] Gasolines suitable for used in preferred embodiments also
include those used to fuel two-cycle (2T) engines. In two-cycle
engines, lubrication oil is added to the combustion chamber and
admixed with gasoline. Combustion results in emissions of unburned
fuel and black smoke. Certain two-cycle engines may be so
inefficient that 2 hours of running such an engine under load may
produce the same amount of pollution as a gasoline-powered car
equipped with a typical emission control system that is driven
130,000 miles. In a typical two-cycle engine vehicle, 25 to 30% of
the fuel leaves the tailpipe unburned. In California alone there
are approximately 500,000 two-cycle engines, which produce the
equivalent of the emissions of 4,000,000 million gasoline powered
cars. In Malaysia and throughout much of Asia, China and India the
problem is much more severe. Malaysia has 4,000,000 two-cycle
engines, which produce pollution equivalent to that from 32,000,000
automobiles.
Diesel Fuels
[0144] The diesel fuels utilized in the preferred embodiments
include that portion of crude oil that distills out within the
temperature range of approximately 150.degree. C. to 370.degree. C.
(698.degree. F.), which is higher than the boiling range of
gasoline. Diesel fuel is ignited in an internal combustion engine
cylinder by the heat of air under high compression--in contrast to
motor gasoline, which is ignited by an electrical spark. Because of
the mode of ignition, a high cetane number is required in a good
diesel fuel. Diesel fuel is close in boiling range and composition
to the lighter heating oils. There are two grades of diesel fuel,
established by the ASTM: Diesel 1 and Diesel 2. Diesel 1 is a
kerosene-type fuel, lighter, more volatile, and cleaner burning
than Diesel 2, and is used in engine applications where there are
frequent changes in speed and load. Diesel 2 is used in industrial
and heavy mobile service.
[0145] Suitable diesel fuels may include both high and low sulfur
fuels. Low sulfur fuels generally include those containing 500 ppm
(on a weight basis) or less sulfur, and may contain as little as
100, 95, 90, 85, 80, 75, 70, 65, 60, 55, 50, 45, 40, 35, 30, 25,
20, 15, 20, or 5 ppm or less sulfur, or even 0 ppm sulfur, for
example, in the case of synthetic diesel fuels. High sulfur diesel
fuels typically include those containing more than 500 ppm sulfur,
for example, as much as 1, 2, 3, 4, or 5 wt. % sulfur or more.
[0146] Fuels that boil in a range of 150.degree. C. to 330.degree.
C. work best in diesel engines because they are completely consumed
during combustion, with no waste of fuel or excess emissions.
Paraffins, which offer the best cetane rating, are preferred for
diesel blending. The higher the paraffin content of a fuel, the
more easily it burns, providing quicker warm-ups and complete
combustion. Heavier crude components that boil at higher ranges,
although less desirable, may also be used. Naphthenes are the next
lightest components and aromatics are the heaviest fractions found
in diesel. Using these heavier components helps minimize diesel
fuel waxiness. At low temperatures, paraffins tend to solidify,
plugging fuel filters.
[0147] In addition to Diesel 1 and Diesel 2 fuels, other fuels
capable of combusting in a diesel engine may also be used as base
fuels in various embodiments. Such fuels may include, but are not
limited to, those based on coal dust emulsions and vegetable oil.
The vegetable oil based diesel fuels are commercially available and
are marketed under the name "bio-diesel." They contain a blend of
methyl esters of fatty acids of vegetable origin and are often used
as an additive to conventional diesel fuels.
Fuel Oils
[0148] Fuel oils are complex and variable mixtures of alkanes and
alkenes, cycloalkanes and aromatic hydrocarbons, containing low
percentages of sulfur, nitrogen, and oxygen compounds. Kerosene
fuel oils are manufactured from straight-run petroleum distillates
from the boiling range of kerosene. Other distillate fuel oils
contain straight-run middle distillate, often blended with
straight-run gas oil, light vacuum distillates, and light cracked
distillates. The main components of residual fuel oils are the
heavy residues from distillation and cracking operations. Fuel oils
are used mainly in industrial and domestic heating, as well as in
the production of steam and electricity in power plants.
[0149] Gas oils are obtained from the lowest fraction from
atmospheric distillation of crude oil, while heavy gas oils are
obtained by vacuum redistillation of the residual from atmospheric
distillation. Gas oil distills between 180.degree. C. and
380.degree. C. and is available in several grades, including diesel
oil for diesel compression ignition, light heating oil, and other
gas oil including heavy gas oils which distill between 380.degree.
C. and 540.degree. C. Heavy fuel oil residual is made up of
distillation residue.
[0150] In certain applications, an emulsion of the fuel oil in
water may be combusted. The additive formulations of preferred
embodiments may be used to reduce the emissions produced from
burning such fuels.
[0151] Residual fuels are typically pre-heated to 116.degree. C.
(240.degree. F.) prior to combustion. This elevated temperature
converts the fuel from a solid to a more liquid state and reduces
the viscosity. This reduction in viscosity allows the fuel to be
properly atomized for combustion. The additive formulations of
certain embodiments may be sensitive to such elevated temperatures,
and exposure to such elevated temperatures for extended periods of
time may result in a deterioration in their effectiveness in
reducing emissions. To minimize the exposure time of the additive
formulation in the residual fuel to elevated temperatures prior to
combustion, it is generally preferred to use a Metered Injection
Pumping System (MIPS), illustrated in FIG. 1, to additize the fuel.
A MIPS system is able to sense residual fuel flow to the combustion
chamber and make adjustments to additization rates automatically so
as to ensure a constant level of additive in the fuel. A MIPS is
connected to the residual fuel after the recirculation of the fuel,
typically after the re-circulating valve. As a result of this
connection, the only fuel being additized is the fuel entering into
the combustion chamber of the boiler. Typically the fuel is
recirculated from the holding tank. The residual fuel is heated and
maintained at a predetermined temperature of approximately
240.degree. F. This temperature is generally necessary for proper
atomization of such fuel, which is typically a solid at ambient
temperatures.
[0152] In the MIPS system illustrated in FIG. 1, the fuel is
recirculated in a heavy insulated 10 cm (4 inch) black pipe above
ground. Above ground pipes are preferred to provide easy
accessibility for external heating. A one way valve is placed in
the fuel line approximately 1.2 to 1.8 m (4 to 6 feet) from the
value to the combustion chamber. The pressure of the residual oil
is usually about 103 to about 172 kPa (about 15 to about 25 psi).
The MIPS is hooked-up to the fuel line after recirculation but just
prior to combustion. The MIPS is on a flat square steel platform
approximately 0.9 m by 0.9 m (3 feet by 3 feet). The residual fuel
enters the MIPS through a splice in the fuel line pipe connection.
Once entering this pipe, the fuel passes through an extremely
accurate fuel oil meter with a pulse signal head, which generates
an electrical signal. This signal is sent to the prominent
diaphragm positive placement injection pump that is calibrated to
supply a predetermined amount of additive to the residual fuel. The
additive is atomized, typically under a pressure of 1034 kPa (150
psi), into the residual fuel as it enters the motionless mixer, a
1.9 cm by 23 cm (3/4 inch by 9 inch) long pulsation dampener, which
contains a series of flights which, in turn, spin the fuel 360
degrees several times. A manual calibration tube is placed on the
MIPS platform for accuracy and allows an on site calibration. In
line fuel filters are used to filter the additive from the holding
tank to the MIPS accumulator. The pump is positive placement so as
to provide a continuous supply of additive. Once the fuel is
treated with additive and is mixed, it is sent directly to the
atomization nozzles and into the combustion zone of the boiler. In
operation, the residual fuel flows through the fuel meter, which
automatically sends a signal to the pump. The signal establishes
the amount of additive that is dispensed into the residual fuel.
The signal also allows the residual fuel to flow at a rate of 30
liters to 757 liters per hour (8 gallons to 200 gallons per hour)
while the pump automatically dispenses a calibrated predetermined
amount of additive. The complete process takes less than 15
seconds, a time sufficiently short such that the residual fuel does
not substantially cool and the formulation of preferred embodiments
does not substantially pre-oxidize.
Coal-based Fuels
[0153] The additive formulations of preferred embodiments may be
used in conjunction coal or coal-in-water emulsions. The additive
may be applied to the coal or added to the emulsion using
techniques well known in the art. For example, it is preferred to
spray the additive formulation of preferred embodiments onto
pulverized coal prior to combustion. When the coal is in the form
of an emulsion in water, the additive formulation may be added
directly to the emulsion.
Other Fuels
[0154] The additive formulations of preferred embodiments are
suitable for use with other materials that upon combustion yield
nitrogen oxides, carbon monoxide, particulates, and other
undesirable combustion products. For example, the additive may be
incorporated into, e.g., charcoal briquettes, wood-containing fuels
such as Pres-to-Logs.RTM., and waste to be burned in incinerators,
including large municipal waste combustors, small municipal waste
combustors, hospital/medical/infectious waste incinerators,
commercial and industrial solid waste incineration units, hazardous
waste incinerators, manufacturing waste incinerators, or industrial
boilers and furnaces that burn waste.
EXAMPLES
Oil Extraction from Barley Grass
[0155] 20 grams of dry, ground barley grass were extracted into a
volume of n-hexane. After the extraction was completed, the extract
was distilled to remove the n-hexane. After the n-hexane was
distilled, the temperature of the extract was raised to 101.degree.
C. and maintained at that temperature for 30 minutes to remove any
water present in the extract. The extracted oil was transferred to
a sample bottle and kept in a vacuum oven at 50.degree. C. for 8
hours to remove any residual water or solvent present in the
extract. The extract was then weighed and the percent oil in the
sample (on a dry basis) was measured.
[0156] The grass subjected to the extraction procedure described
above included two batches, Grass A and Grass B. Grass A was
supplied in the form of a dried and ground material. Grass B was
supplied in raw form, and required drying and grinding prior to
extraction.
[0157] The effect of extraction time was investigated for Grass A.
20 grams of the dried grass was extracted with 125 ml of n-hexane
at a temperature of 70.degree. C. for 2.0, 4.0, 6.0, and 8 hours.
The results, provided in the following Table, suggest that an
extraction time of approximately 6 hours is generally sufficient to
provide a satisfactory yield of oil extract from dried barley
grass.
2TABLE 2 Oil Weight % Oil Extraction Time (hours) (g per 20 g
sample) (Dry Basis) 2.0 0.1829 0.942 4.0 0.2522 1.299 6.0 0.4400
2.266 8.0 0.3880 1.998
[0158] A sample of Grass B was dried and ground. The sieve test
results for the ground sample of Grass B was as follows:
3TABLE 3 Retained by Mesh No. Weight Percentage 10 5.10 2.47 14
62.14 30.05 16 72.40 35.00 18 45.83 22.16 >18 21.37 10.33 Total
206.83 100.00
[0159] The effects of extraction temperature, time, and n-hexane
volume were investigated, as well as differences between ground and
unground barley grass. The results suggest that higher oil yields
are obtained for ground grass, and that extraction times of from 1
to 4 hours were sufficient to provide satisfactory oil extract
yields. As the volume of n-hexane used in the extraction was
reduced from 250 to 200 ml, the resulting oil extract yield was
observed to drop substantially, however, a reduction from 200 to
125 ml did not have a substantial effect on oil extract yield. A
drop in temperature from 78.degree. C. to 60.degree. C. produced a
substantial drop in oil extract yield.
4TABLE 4 Extraction Oil Experiment Temp. n-Hexane Time Weight % Oil
Number (.degree. C.) (ml) (hr) (g) (Dry Basis) 1 78 250 4.0 0.125
0.676 (not ground) 2 78 250 1.0 0.708 3.540 3 78 250 3.0 0.718
3.590 4 78 250 4.0 0.704 3.520 5 78 200 4.0 0.589 2.945 6 78 200
2.0 0.551 2.755 7 78 125 4.0 0.591 2.955 8 60 250 4.0 0.539
2.695
[0160] The extraction data indicate that under similar extraction
conditions, Grass B gave a better oil yield than Grass A. While not
wishing to be bound to any explanation, it is possible that growing
conditions or other factors may result in different oil yields. The
ratio of grass to solvent appears to have a substantial effect on
the amount of oil extracted. A ratio of 250 ml of n-hexane per 20 g
of grass is expected to produce satisfactory oil extract yields. At
this ratio, the extraction time did not have a significant effect
on the yield of oil extract. Particle size of the grass had a large
effect on oil yields, with ground grass yielding more oil than
unground grass. An extraction temperature of 78.degree. C. provided
a satisfactory yield of oil extract. However, a temperature of
60.degree. C. did not. The boiling point of n-hexane is 68.degree.
C, which suggests that extraction temperatures above the boiling
point of n-hexane may produce satisfactory oil extract yields.
[0161] A large-scale extraction was run on two lots of barley
grass. One lot consisted of 1.8 kg dry material and the other lot
consisted of 5.5 kg wet material. Both lots were flaked through
Ferrell-Ross flaking rolls with the air gap set at 3.0 mm, and 6.8
kg of the flaked material was sent to a steam jacketed pilot plant
stainless steel extractor vessel for a single wash. 102 liters of
commercial hexane was used as the solvent. The extraction was
conducted for 6 hours at a temperature of 49-51.degree. C. After
the extraction was completed, the solvent and material remained in
the reactor at ambient temperature for a few days prior to recovery
of the extract. The extract was recovered in a thin film evaporator
to yield 454.8 grams of oil extract (a yield of approximately 6.7
wt. %).
Gasoline--OR-1
[0162] Small Batch Manufacturing--Toluene (200 ml, industrial
grade) was placed in a 400 ml glass Erlenmeyer flask. A nitrogen
"blanket" was placed over the toluene by allowing nitrogen gas to
flow into the space above the toluene in the flask. 4 ml jojoba oil
and 4 g of .beta.-carotene were added to the toluene and a solution
prepared. The solution, at a temperature between ambient but below
approximately 32.degree. C. was stirred for approximately 10 to 20
minutes. The extent of solvation of the jojoba oil and
.beta.-carotene in the toluene was determined by shining a light at
an angle through the solution so as to highlight any undissolved
particles floating in the solution. After the jojoba oil and
.beta.-carotene were fully solvated, the solution of jojoba oil and
.beta.-carotene in toluene was poured into a 5000 ml Erlenmeyer
flask containing 3000 ml of No. 1 diesel fuel. The flask containing
the solution of jojoba oil in toluene was rinsed with excess No. 1
diesel fuel, and the rinsings were added to the contents of the
5000 ml flask. Additional No. 1 diesel was then added to the flask
to yield a total of 3785 ml of solution. The solution was heated
and stirred to thoroughly ensure all components were mixed. The
additive package, labeled "Small Batch Additive C" was then stored
in a 1 gallon metal container with nitrogen in the headspace prior
to use.
[0163] 200 ml toluene was placed in a 400 ml glass Erlenmeyer
flask. A nitrogen "blanket" was placed over the toluene as
described above. 19.36 g of oil extract from vetch and 4 ml of
jojoba oil were added to the toluene and a solution prepared by
heating to a temperature of approximately 38.degree. C. to
43.degree. C. and stirring the mixture for approximately 20 to 30
minutes. The extent of solvation of the oil extract of vetch and
jojoba oil in the toluene was determined by shining a light on the
solution to detect any undissolved particles in the solution. After
the oil extract of vetch and jojoba oil were fully solvated, the
solution was poured into a 5000 ml Erlenmeyer flask containing 3000
ml of No. 1 diesel fuel. The flask containing the solution of oil
extract of vetch and jojoba oil in toluene was rinsed with excess
No. 1 diesel fuel, and the rinsings were added to the contents of
the 5000 ml flask. Additional No. 1 diesel was then added to the
flask to yield a total of 3785 ml of solution. The solution was
heated and stirred to thoroughly ensure all components were mixed.
The additive, labeled "Small Batch Additive A" was then stored in a
1 gallon metal container with nitrogen in the headspace prior to
use.
[0164] Small Batch Additives A and C. are then combined in a
regular unleaded gasoline at a predetermined ratio. The amounts
below correspond to the amount of each additive present in 3785 ml
(one gallon) of additized gasoline.
[0165] For the United States, the ratios in Table 5 are preferred,
depending upon the elevation at which the fuel is to be
combusted:
5TABLE 5 United States Altitude Additive A Additive C Below 762 m
(2500 ft.) 2.5 ml 0.5 ml 762 m to 1524 m (2500 ft. to 5000 ft.) 1.2
ml 0.8 ml Above 1524 m (5000 ft.) 3.6 ml 0.8 ml
[0166] For Mexico, where high mercaptan levels in gasoline are a
concern, the ratios in Table 6 are preferred, depending upon the
elevation at which the fuel is to be combusted:
6TABLE 6 Mexico Altitude Additive A Additive C Below 762 m (2500
ft.) 2.5 ml 4.5 ml 762 m to 1524 m (2500 ft. to 5000 ft.) 1.2 ml
4.8 ml Above 1524 m (5000 ft.) 3.6 ml 5.0 ml
[0167] Although the above additive levels may be preferred for
certain embodiments, in other embodiments it may be preferred to
have other additive levels. For example, Small Batch Additive A may
be present at about 0.5 ml or less up to about 10 ml or more per
3785 ml of additized gasoline, preferably at 0.6, 0.7, 0.8, 0.9, 1,
1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2, 2.1, 2.2, 2.3, 2.4,
2.5, 2.6, 2.7, 2.8, 2.9, 3.0, 3.1, 3.2, 3.3, 3.4, 3.5, 3.6, 4, 4.5,
5, 6, 7, 8, or 9 ml per 3785 ml of additized gasoline, and Small
Batch Additive C may be present at about 0.5 ml or less up to about
10 ml or more per 3785 ml of additized gasoline, preferably at 0.6,
0.7, 0.8, 0.9, 1, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2,
2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7, 2.8, 2.9, 3.0, 3.1, 3.2, 3.3,
3.4, 3.5, 3.6, 4, 4.5, 5, 6, 7, 8, or 9 ml per 3785 ml of additized
gasoline.
Gasoline--OR-1
[0168] Large Batch Manufacturing--Commercial Applications--1600 ml
toluene was placed in a 2000 ml glass Erlenmeyer flask. A nitrogen
"blanket" was placed over the toluene as described above. 32 ml
jojoba oil and 32 g of .beta.-carotene were added to the toluene
and a solution prepared by heating and stirring the mixture as
described above (namely, stirring for 10 to 20 minutes at a
temperature of from ambient to below approximately 32.degree. C).
The extent of solvation of the jojoba oil and .beta.-carotene in
the toluene was determined as described above. After the jojoba oil
and .beta.-carotene were fully solvated, the solution of jojoba oil
and .beta.-carotene in toluene was poured into a 5000 ml Erlenmeyer
flask containing 2000 ml of No. 1 diesel fuel. The flask containing
the solution of jojoba oil in toluene was rinsed with excess No. 1
diesel fuel, and the rinsings were added to the contents of the
5000 ml flask. Additional No. 1 diesel was then added to the flask
to yield a total of 3785 ml of solution. The solution was heated
and stirred to thoroughly ensure all components were mixed. The
additive package, labeled "Large Batch Additive C" was then stored
in a 1 gallon metal container with nitrogen in the headspace prior
to use.
[0169] 1600 ml toluene was placed in a 2000 ml glass Erlenmeyer
flask. A nitrogen "blanket" was placed over the toluene as
described above. 154.88 g of oil extract from vetch and 32 ml of
jojoba oil were added to the toluene and a solution prepared by
heating and stirring the mixture as described above (namely,
stirring for 30 to 30 minutes at a temperature of approximately
38.degree. C. to 43.degree. C). The extent of solvation of the oil
extract of vetch and jojoba oil in the toluene was determined by
shining a light on the solution to detect any undissolved particles
in the solution. After the oil extract of vetch and jojoba oil were
fully solvated, the solution was poured into a 5000 ml Erlenmeyer
flask containing 2000 ml of No. 1 diesel fuel. The flask containing
the solution of oil extract of vetch and jojoba oil in toluene was
rinsed with excess No. 1 diesel fuel, and the rinsings were added
to the contents of the 5000 ml flask. Additional No. 1 diesel was
then added to the flask to yield a total of 3785 ml of solution.
The solution was heated and stirred to thoroughly ensure all
components were mixed. The additive, labeled "Large Batch Additive
A" was then stored in a 1 gallon metal container with nitrogen in
the headspace prior to use.
[0170] Large Batch Additives A and C are then combined in a regular
unleaded gasoline at a predetermined ratio. The amounts below
correspond to the amount of each additive present in 3785 ml (one
gallon) of additized gasoline.
[0171] For the United States, the ratios in Table 7 are preferred,
depending upon the elevation at which the fuel is to be
combusted:
7TABLE 7 United States Altitude Additive A Additive C Below 762 m
(2500 ft.) 0.3125 ml 0.0625 ml 762 m to 1524 m (2500 ft. to 5000
ft.) 0.4 ml 0.1 ml Above 1524 m (5000 ft.) 0.45 ml 0.1 ml
[0172] For Mexico, where high mercaptan levels in gasoline are a
concern, the ratios in Table 8 are preferred, depending upon the
elevation at which the fuel is to be combusted:
8TABLE 8 Mexico Altitude Additive A Additive C Below 762 m (2500
ft.) 0.3125 ml 0.5625 ml 762 m to 1524 m (2500 ft. to 5000 ft.) 0.4
ml 0.6 ml Above 1524 m (5000 ft.) 0.45 ml 0.625 ml
[0173] Although the above additive levels may be preferred for
certain embodiments, in other embodiments it may be preferred to
have other additive levels. For example, Large Batch Additive A may
be present at about 0.1 ml or less up to about 1 ml or more per
3785 ml of additized gasoline, preferably at 0.15, 0.2, 0.25, 0.3,
0.35, 0.4, 0.45, 0.5, 0.55, 0.6, 0.65, 0.7, 0.75, 0.8, 0.85, 0.9,
or 0.95 ml per 3785 ml of additized gasoline, and Large Batch
Additive C may be present at about 0.02 ml or less up to about 1 ml
or more per 3785 ml of additized gasoline, preferably at 0.03,
0.04, 0.05, 0.06, 0.07, 0.08, 0.09, 0.1, 0.15, 0.2, 0.25, 0.3,
0.35, 0.4, 0.45, 0.5, 0.55, 0.6, 0.65, 0.7, 0.75, 0.8, 0.85, 0.9,
or 0.95 ml per 3785 ml of additized gasoline.
[0174] While not wishing to be bound by any theory, it is believed
that the fuel additive OR-1 allows a more complete combustion of
gasoline by eliminating quenching, spiking, and/or inconsistencies
in the flame profile, in other words, by creating a smoother bum.
FIG. 2 illustrates a hypothetical temperature versus time curve for
the piston cycle of treated and untreated fuel. The difference
between point A and point B corresponds to NO.sub.x reduction. The
treated, or "smoother" flame hits the catalytic converter at a
higher temperature and in a shorter amount of time, referred to as
the catalyst light-off time (point C). This is believed to create
an additional NO.sub.x reduction and also to create a HC and CO
reduction as well. When introducing higher temperatures at faster
time cycles, it is believed that OR-1 keeps the catalytic converter
in more of a "green state," burning off gums, resins, and carbon
deposits, hence the reduction in significant emissions observed for
use of the additive. Increased fuel economy is believed to result
from an overall more efficient burn in the combustion chamber.
Diesel--OR-2
[0175] Small Batch Manufacturing--Small Batch Additive A and Small
Batch Additive C are prepared as described above, and then combined
in a Number 2 low Sulfur Diesel Fuel at a predetermined ratio. The
amounts below correspond to the amount of each additive present in
3785 ml (one gallon) of additized diesel fuel.
[0176] For the United States, the ratios in Table 9 are preferred,
depending upon the elevation at which the fuel is to be
combusted:
9TABLE 9 United States Altitude Additive A Additive C Below 762 m
(2500 ft.) 2.5 ml 1.5 ml 762 m to 1524 m (2500 ft. to 5000 ft.) 2.5
ml 2.0 ml Above 1524 m (5000 ft.) 2.5 ml 2.5-3.0 ml
[0177] For Mexico, the ratios in Table 10 are preferred, depending
upon the elevation at which the fuel is to be combusted:
10TABLE 10 Mexico Altitude Additive A Additive C Below 762 m (2500
ft.) 2.5 ml 1.2 ml 762 m to 1524 m (2500 ft. to 5000 ft.) 2.5 ml
2.0 ml Above 1524 m (5000 ft.) 2.5 ml 3.0 ml
[0178] Although the above additive levels may be preferred for
certain embodiments, in other embodiments it may be preferred to
have other additive levels. For example, Small Batch Additive A may
be present at about 0.5 ml or less up to about 10 ml or more per
3785 ml of additized diesel fuel, preferably at 0.6, 0.7, 0.8, 0.9,
1, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2, 2.1, 2.2, 2.3,
2.4, 2.5, 2.6, 2.7, 2.8, 2.9, 3.0, 3.1, 3.2, 3.3, 3.4, 3.5, 3.6, 4,
4.5, 5, 6, 7, 8, or 9 ml per 3785 ml of additized diesel fuel, and
Small Batch Additive C may be present at about 0.5 ml or less up to
about 10 ml or more per 3785 ml of additized diesel fuel,
preferably at 0.6, 0.7, 0.8, 0.9, 1, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6,
1.7, 1.8, 1.9, 2, 2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7, 2.8, 2.9, 3.0,
3.1, 3.2, 3.3, 3.4, 3.5, 3.6, 4, 4.5, 5, 6, 7, 8, or 9 ml per 3785
ml of additized diesel fuel.
Diesel--OR-2
[0179] Large Batch Manufacturing--Commercial Applications--Large
Batch Additive A and Large Batch Additive C. are prepared as
described above, and then combined in a Number 2 Low Sulfur Diesel
Fuel at a predetermined ratio. The amounts below correspond to the
amount of each additive present in 3785 ml (one gallon) of
additized diesel fuel.
[0180] For the United States, the ratios in Table 11 are preferred,
depending upon the elevation at which the fuel is to be
combusted:
11TABLE 11 United States Altitude Additive A Additive C Below 762 m
(2500 ft.) 0.3125 ml 0.15 ml 762 m to 1524 m (2500 ft. to 5000 ft.)
0.3125 ml 0.25 ml Above 1524 m (5000 ft.) 0.3125 ml 0.375 ml
[0181] For Mexico, the ratios in Table 12 are preferred, depending
upon the elevation at which the fuel is to be combusted:
12TABLE 12 Mexico Altitude Additive A Additive C Below 762 m (2500
ft.) 0.3125 ml 0.15 ml 762 m to 1524 m (2500 ft. to 5000 ft.)
0.3125 ml 0.25 ml Above 1524 m (5000 ft.) 0.3125 ml 0.375 ml
[0182] Although the above additive levels may be preferred for
certain embodiments, in other embodiments it may be preferred to
have other additive levels. For example, Large Batch Additive A may
be present at about 0.1 ml or less up to about 1 ml or more per
3785 ml of additized diesel fuel, preferably at 0.15, 0.2, 0.25,
0.3, 0.35, 0.4, 0.45, 0.5, 0.55, 0.6, 0.65, 0.7, 0.75, 0.8, 0.85,
0.9, or 0.95 ml per 3785 ml of additized diesel fuel, and Large
Batch Additive C may be present at about 0.05 ml or less up to
about 1 ml or more per 3785 ml of additized diesel fuel, preferably
at 0.06, 0.07, 0.08, 0.09, 0.1, 0.15, 0.2, 0.25, 0.3, 0.35, 0.4,
0.45, 0.5, 0.55, 0.6, 0.65, 0.7, 0.75, 0.8, 0.85, 0.9, or 0.95 ml
per 3785 ml of additized diesel fuel.
Residual Fuel--OR-3
[0183] Small Batch Manufacturing--Fuel Economy--Small Batch
Additive C was prepared as described above and was added to a High
Residual or Bunker C fuel as a fuel economy additive.
[0184] For Mexico, 4.5 ml of Small Batch Additive C is preferably
present in 3785 ml (one gallon) of additized High Residual or
Bunker C fuel. However, for other countries or in various other
resid fuel formulations, the additive may be present at about 0.1
ml or less up to about 100 ml or more, preferably at 0.05, 1, 1.5,
2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, or 50 ml
per 3785 ml of additized resid fuel. Moreover, it may be preferred
in certain embodiments to include as additional additives one or
more plant oil extracts such as oil extract of vetch and/or thermal
stabilizers such as jojoba oil, or to use as a resid fuel additive
an additive combination suitable for use in gasoline, diesel, or
other hydrocarbon fuels as described in the preferred embodiments
herein.
[0185] Small Batch Manufacturing--Fuel Economy and Reduced
Emissions--200 ml toluene was placed in a 400 ml glass Erlenmeyer
flask. A nitrogen "blanket" was placed over the toluene as
described above. 8 ml of jojoba oil and 4 g .beta.-carotene were
added to the toluene and a solution prepared by heating and
stirring for 10 to 20 minutes at a temperature of from ambient to
below approximately 32.degree. C. The extent of solvation was
determined by shining a light on the solution to detect any
undissolved particles in the solution. After the jojoba oil and
.beta.-carotene were fully solvated, the solution was poured into a
5000 ml Erlenmeyer flask containing 3000 ml of No. 2 diesel fuel.
The flask containing the solution of jojoba oil and .beta.-carotene
in toluene was rinsed with excess No. 2 diesel fuel, and the
rinsings were added to the contents of the 5000 ml flask. 19.36 g
oil extract of vetch was added to the flask and a solution prepared
by heating and stirring the mixture. Additional No. 2 diesel was
then added to the flask to yield a total of 3785 ml of solution.
The solution was heated and stirred to thoroughly ensure all
components were mixed. The additive, labeled "Small Batch Additive
CA" was then stored in a 1 gallon metal container with nitrogen in
the headspace prior to use.
[0186] Small Batch Additive CA is combined in a High Residual or
Bunker C fuel at a predetermined ratio. In various resid fuel
formulations, the additive may be present at about 0.1 ml or less
up to about 100 ml or more, preferably at 0.5, 1, 1.5, 2, 2.5, 3,
3.5, 4, 4.5, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, or 50 ml per 3785
ml of additized resid fuel.
Residual Fuel--OR-3
[0187] Large Batch Manufacturing--Commercial Applications--Fuel
Economy--Large Batch Additive C is prepared as described above,
except that No. 2 Diesel fuel is substituted for No. 1 Diesel fuel.
The additive is then combined in a High Residual or Bunker C fuel
at a predetermined ratio. In the United States, preferably 2 to 4
ml of additive is present per 3785 ml (1 gal.) of fuel. In Mexico,
preferably 0.5625 to 4 ml of additive is present per 3785 ml (1
gal.) of fuel. However, in other countries or in various other
resid fuel formulations, the additive may be present at about 0.1
ml or less up to about 100 ml or more, preferably at 0.5, 1, 1.5,
2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, or 50 ml
per 3785 ml of additized resid fuel. Moreover, it may be preferred
in certain embodiments to include as additional additives one or
more plant oil extracts such as oil extract of vetch and/or thermal
stabilizers such as jojoba oil, or to use as a resid fuel additive
an additive combination suitable for use in gasoline, diesel, or
other hydrocarbon fuels as described in the preferred embodiments
herein.
[0188] Large Batch Manufacturing--Fuel Economy and Reduced
Emissions--1600 ml toluene was placed in a 2000 ml glass Erlenmeyer
flask. A nitrogen "blanket" was placed over the toluene as
described above. 32 ml of jojoba oil and 32 g .beta.-carotene were
added to the toluene and a solution prepared by heating and
stirring for 10 to 20 minutes at a temperature of from ambient to
below approximately 32.degree. C. The extent of solvation of the
oil extract of vetch and jojoba oil in the toluene was determined
by shining a light on the solution to detect any undissolved
particles in the solution. After the oil extract of vetch and
jojoba oil were fully solvated, the solution was poured into a 5000
ml Erlenmeyer flask containing 2000 ml of No. 2 diesel fuel. The
flask containing the solution of jojoba oil and .beta.-carotene in
toluene was rinsed with excess No. 2 diesel fuel, and the rinsings
were added to the contents of the 5000 ml flask. 154.88 g of oil
extract from vetch was added to the flask and a solution prepared
by heating and stirring the mixture. Additional No. 2 diesel was
then added to the flask to yield a total of 3785 ml of solution.
The solution was heated and stirred to thoroughly ensure all
components were mixed. The additive, labeled "Large Batch Additive
CA" was then stored in a 1 gallon metal container with nitrogen in
the headspace prior to use.
[0189] Large Batch Additive CA is combined in a High Residual or
Bunker C fuel at a predetermined ratio. In the United States,
preferably 2 to 4 ml of additive is present per 3785 ml (1 gal.) of
fuel. In Mexico, preferably 0.5625 to 4 ml of additive is present
per 3785 ml (1 gal.) of fuel. However, in other countries or in
various other resid fuel formulations, the additive may be present
at about 0.1 ml or less up to about 100 ml or more, preferably at
0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1, 1.5, 2, 2.5, 3, 3.5, 4,
4.5, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, or 50 ml per 3785 ml of
additized resid fuel.
Additives for Two-cycle Engines--OR-2T
[0190] Several tests were conducted in Malaysia on the combustion
in a two-cycle engine of a fuel containing a formulation of a
preferred embodiment. The tests were performed to assess the
effects of an OR-2T additive, described below, in comparative
analysis testing between unadditized and additized Petronas 2T oil
(referred to in the following table as "2T").
[0191] OR-2T was added into selected 2XT Sprinta JASO FC equivalent
2T oil in various proportions according to blending done by a
standard protocol of adding incremental small amounts of OR-2T
additive to the 2T oil. The final ratio of the 2XT Sprinta JASO FC
plus OR-2T additive in relation to the gasoline fuel was 1:20. This
ratio was maintained throughout the test program. However, the
proportion of the OR-2T additive added to the 2XT Sprinta JASO FC
was varied.
[0192] The test equipment included a Hartridge Model 4 smoke meter
from Lucas Assembly and test Systems, England, equipped with
automatic printout, and a Yamaha RT600A 49.9cm.sup.3 two-cycle test
engine. The gasoline fuel tested was Petronas Primas PX2 and the 2T
Engine oils included Sprinta 2Y9(FB) and Sprinta 2XT(FC).
[0193] Measurement of the smoke level was carried out using the
Hartridge Model-4, with an integrated internal light source and
smoke column; averaging once between 100-110.degree. C. and another
between 110-120.degree. C. The results were reported in Hartridge
Smoke level Units (HSU) ranging from 0 to 100 HSU per loading
cycle. A series of smoke level readings were conducted initially to
obtain a good repeatability for the baseline reading using the
Primas PX2 and the Sprinta 2XT Racing oil. The candidate (OR-2T
additized 2XT Sprinta engine oil) were evaluated in accordance to
the specified procedure to obtain smoke level readings. The smoke
level in HSU was recorded and tabulated to the candidate used in
the testing. Petronas performed all testing at their research
facility located in Shah Alam, Malaysia.
[0194] The OR-2T additive for two-cycle engines was able to achieve
a 50% reduction in the smoke from this two-cycle engine smoke test.
The additive was added to the oil, mixed into the oil, and then the
oil was poured directly into the gasoline fuel tank. The average
reduction was well over 40%, in some cases as great as a 50 to 55%
reduction in smoke.
[0195] The OR-2T formula for this two-cycle additive was prepared
from Small Batch Additive A and Small Batch Additive C Reductions
in smoke levels observed are reported in Table 13.
13TABLE 13 % change in Formulation smoke levels Unadditized base
fuel (smoke point of 90.85 to 92.3) -- A 0.28 ml + C 0.65 ml in a
gallon of 2 T at a ratio of 1:20 -8% A 1.5 ml + C 1.22 ml in a
gallon of 2 T at a ratio of 1:20 -22% A 0.28 ml + C 1.42 ml in a
gallon of 2 T at a ratio of 1:20 -30% A 1.1 ml + C 10 ml in a
gallon of 2 T at a ratio of 1:20 -31% A 1.1 ml + C 20 ml in a
gallon of 2 T at a ratio of 1:20 -52% A 0.6 ml + C 20 ml in a
gallon of 2 T at a ratio of 1:20 -48%
[0196] Although the above additive levels may be preferred for
certain embodiments, in other embodiments it may be preferred to
have other additive levels. For example, Small Batch Additive A may
be present at about 0.05 ml or less up to about 100 ml or more per
3785 ml of additized two-cycle oil, preferably at 0.2, 0.3, 0.4,
0.5, 0.6, 0.7, 0.8, 0.9, 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7,
8, 9, 10, 15, 20, 30, 40, or 50 ml per 3785 ml of additized 2T
fuel, and Small Batch Additive C may be present at about 0.05 ml or
less up to about 100 ml or more per 3785 ml of additized two-cycle
fuel, preferably at 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1, 1.5,
2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, or 50 ml
per 3785 ml of additized 2T oil. The additized 2T oil is typically
added to a base gasoline at a treat rate of about 1:10 (on a weight
basis) to 1:40 (on a weight basis), preferably from about 1:11,
1:12, 1:13, 1:14, 1:15, 1:16, 1:17, 1:18, or 1:19 (on a weight
basis) to about 1:21, 1:22, 1:23, 1:24, 1:25, 1:26, 1:27, 1:28,
1:29, 1:30, 1:35, or 1:40 (on a weight basis). In certain
embodiments, however, higher or lower ratios may be preferred.
Cetane Improver
[0197] A composition and method for increasing the amount of cetane
in fuel is provided. In one embodiment, the cetane improver
comprises .beta.-carotene that was prepared under an inert
atmosphere. Unexpectedly, it was discovered that .beta.-carotene,
which was dissolved in an inert atmosphere, raised the level of
cetane in No. 2 diesel fuel more effectively and maintained the
raised cetane level longer than .beta.-carotene prepared by
conventional methods. In preferred embodiments, a cetane improver
is prepared by mixing .beta.-carotene with a toluene carrier under
an inert atmosphere, and adding an alkyl nitrate, for example,
2-ethylhexyl nitrate. The preferred cetane improver prepared by the
methods described herein increased the level of cetane in No. 2
diesel fuel in a synergistic fashion.
[0198] In a preferred embodiment, the cetane improver can be
formulated by the following method. Under an inert atmosphere,
(e.g., nitrogen, helium, or argon) three grams of .beta.-carotene
(1.6 million International units of vitamin A activity per gram)
are dissolved in 200 ml of a liquid hydrocarbon carrier comprising
toluene. It is preferred to dissolve the .beta.-carotene with
heating and stirring. .beta.-Carotene dissolved or otherwise
prepared under an inert atmosphere is referred to as
"non-oxygenated .beta.-carotene." Next, approximately 946
milliliters of a 100% solution of 2-ethylhexyl nitrate is added to
the mixture and toluene is added so as to obtain a total volume of
3.785 liters.
[0199] The following components may be used in combination with
.beta.-carotene in cetane improvers of preferred embodiments:
butylated hydroxytoluene, lycopene, lutein, all types of
carotenoids, oil extract from carrots, beets, hops, grapes,
marigolds, fruits, vegetables, palm oil, palm kernel oil, palm tree
oil, bell pepper, cottonseed oil, rice bran oil, any plant that is
naturally orange, red, purple, or yellow in color that is growing
in nature, or any other material that may be a natural oxygen
scavenger but yet remains organic in nature.
[0200] The oil extracted from the following products may also be
used in combination with .beta.-carotene: .alpha.-carotene, and
additional carotenoids from algae xeaxabthin, crypotoxanthin,
lycopene, lutein, broccoli concentrate, spinach concentrate, tomato
concentrate, kale concentrate, cabbage concentrate, Brussels
sprouts concentrate and phospholipids. In addition, the oil
extracts from green tea extract, milk thistle extract, curcumin
extract, quercetin, bromelain, cranberry and cranberry powder
extract, pineapple extract. pineapple leaves extract, rosemary
extract, grapeseed extract, ginkgo biloba extract, polyphenols,
flavonoids, ginger root extract, hawthorn berry extract, bilberry
extract, butylated hydroxytoluene, oil extract of marigolds, oil of
hops, oil extract of jojoba, any and all oil extract of carrots,
fruits, vegetables, flowers, grasses, natural grains, leaves from
trees, leaves from hedges, hay, feed stocks for man and animal, and
weeds, the oil extract of any living plant, or the oil extract of
any fresh water or salt water fish, such as shark, including but
not limited to squalene, squalane, all fresh and salt water fish
oils, and fish oil extracts, or the oil extract of animals, such as
whale.
[0201] It should be understood that pure 2-ethylhexyl nitrate is
desired but that other alkyl nitrates or other grades of
2-ethylhexyl nitrate are also suitable. Further, one of skill will
appreciate that other alkyl nitrates or conventional cetane
improvers or ignition accelerators, as described above, perform
similarly to 2-ethylhexyl nitrate and can be substituted
accordingly. Desirably, many different formulations of cetane
improver may be made, each having a different alkyl nitrate or more
than one alkyl nitrate and/or proportions thereof relative to the
.beta.-carotene. Certain such formulations were evaluated for the
ability to raise cetane levels in No. 2 diesel fuel according to
the methods described below. In the embodiment described above, it
is desirable to add the ingredients in the order described above.
However, in other embodiments, variations in the order of addition
can be made.
[0202] The cetane improver prepared as described above is one
embodiment of a "concentrated cetane improver." To improve the
cetane level in No. 2 diesel fuel, approximately 0.1 ml-35 ml of
the concentrated cetane improver is added per one gallon of No. 2
diesel fuel. Preferably, the amount of concentrated cetane improver
added to a gallon of No. 2 diesel fuel is in the range from about
0.3 ml to about 30ml, more desirably, from about 0.5 ml to about 25
ml, still more preferably, from about 0.75 ml to about 20 ml, even
more preferably, from about 1 ml to about 15 ml, and most
preferably, from about 2, 3, 4, or 5 ml to about 6, 7, 8, 9, 10,
11, or 12 ml.
[0203] Cetane testing was performed by independent petroleum
laboratories, each of which was CARB, EPA, and ASTM Certified. The
procedure for testing Cetane is ASTM D-613, a published procedure
that measures the ignition point of No. 2 diesel fuel. The test
data, provided in Tables 14-22, verify that the cetane improver
described herein synergistically improves the level of cetane in
No. 2 diesel fuel. Additive OR-CT was prepared which contained
395.8 parts by weight toluene to 660.6 parts by weight of
2-ethylhexyl nitrate to 0.53 parts by weight of .beta.-carotene.
Various samples of No. 2 diesel fuel were treated to contain 1057
ppm of additive OR-CT (referred to as a "2+2" fuel). An additized
fuel referred to as "1+0.5" in the following tables corresponds to
a fuel treated with 264 ppm OR-CT and 132 ppm 2-ethylhexyl nitrate.
Additized fuel referred to as "4+4" contains 1057 ppm OR-CT and
1057 ppm 2-ethylhexyl nitrate, and additized fuel referred to as
"8+8" contains 2114 ppm OR-CT and 2114 ppm 2-ethylhexyl
nitrate.
14TABLE 14 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel 44.8 -- No. 2 diesel with 8 ml 100%
2-ethylhexyl nitrate 51.8 +7 added No. 2 diesel "8 + 8" 54.4
+9.6
[0204]
15TABLE 15 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel + 2-ethylhexyl 42.5 -- nitrate pretreat No. 2
diesel + 2-ethylhexyl nitrate pretreat "4 + 4" 44.6 +2.1
[0205]
16TABLE 16 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel 37.0 -- No. 2 diesel with 8 ml 100%
2-ethylhexyl nitrate 41.8 +4.8 added No. 2 diesel "4 + 4" 41.9 +4.9
No. 2 diesel "8 + 8" 43.3 +6.3
[0206]
17TABLE 17 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel 32.7 -- No. 2 diesel with 8 ml 100%
2-ethylhexyl nitrate 39.4 +6.7 added No. 2 diesel "4 + 4" 37.3 +4.6
No. 2 diesel "8 + 8" 41.4 +8.7
[0207]
18TABLE 18 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel 40.6 -- No. 2 diesel with 8 ml 100%
2-ethylhexyl nitrate 46.0 +5.4 added No. 2 diesel "2 + 2" 42.6 +2.0
No. 2 diesel "4 + 4" 45.6 +5.0
[0208]
19TABLE 19 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel 34.9 -- No. 2 diesel with 1.5 ml 100%
2-ethylhexyl nitrate 39.9 +5.0 added No. 2 diesel with "1 + 0.5"
38.8 +3.9
[0209]
20TABLE 20 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel 36.4 -- No. 2 diesel with 4 ml 100%
2-ethylhexyl nitrate 40.3 +3.9 added No. 2 diesel "2 + 2" 40.7
+4.3
[0210]
21 TABLE 21 Change Cetane over Formulation Number Baseline Baseline
fuel - No. 2 Diesel 42.2 -- No. 2 diesel "4 + 4" 50.7 +8.5 No. 2
diesel "8 + 8" 60.0 +17.3 Baseline fuel - No. 2 Diesel 47.8 -- No.
2 diesel "4 + 4" 57.4 +9.6 No. 2 diesel "8 + 8" 62.5 +14.7 Baseline
fuel - No. 2 Diesel 51.3 -- No. 2 diesel "4 + 4" 61.0 +9.7 No. 2
diesel "8 + 8" 70.5 +19.2 Baseline fuel - No. 2 Diesel 22.9 -- No.
2 diesel "4 + 4" 31.6 +8.7 No. 2 diesel "8 + 8" 36.6 +13.7 Baseline
fuel - No. 2 Diesel 31.8 -- No. 2 diesel "4 + 4" 39.1 +7.3 No. 2
diesel "8 + 8" 42.1 +10.3 Baseline fuel - No. 2 Diesel 38.0 -- No.
2 diesel "4 + 4" 48.5 +10.5 No. 2 diesel "8 + 8" 51.1 +13.1
Baseline fuel - No. 2 Diesel 49.2 -- No. 2 diesel "4 + 4" 54.6 +5.4
No. 2 diesel "8 + 8" 62.5 +13.3
[0211]
22TABLE 22 Change Difference over Cetane over 2-Ethylhexyl
Formulation Number Baseline Nitrate Baseline fuel - No. 2 Diesel
42.7 -- -- No. 2 diesel "2 + 2" 47.6 +4.9 +0.3 No. 2 diesel with 2
ml 100% 2- 47.3 +4.6 -- ethylhexyl nitrate only Baseline fuel - No.
2 Diesel 47.8 -- -- No. 2 diesel "2 + 2" 53.6 +5.8 +2.3 No. 2
diesel with 2 ml 100% 2- 51.3 +3.5 -- ethylhexyl nitrate only
Baseline fuel - No. 2 Diesel 50.0 -- -- No. 2 diesel "2 + 2" 55.8
+5.3 +2.3 No. 2 diesel with 2.5 ml 100% 2- 53.5 +3.0 -- ethylhexyl
nitrate only Baseline fuel - No. 2 Diesel 23.5 -- -- No. 2 diesel
"2 + 2" 31.8 +8.3 +2.2 No. 2 diesel with 2.5 ml 100% 2- 29.6 +6.1
-- ethylhexyl nitrate only Baseline fuel - No. 2 Diesel 32.4 -- --
No. 2 diesel "2 + 2" 37.9 +5.5 +1.2 No. 2 diesel with 2.5 ml 100%
2- 36.7 +4.3 -- ethylhexyl nitrate only Baseline fuel - No. 2
Diesel 38.9 -- -- No. 2 diesel "2 + 2" 42.0 +3.1 +1.8 No. 2 diesel
with 2.5 ml 100% 2- 40.2 +1.3 -- ethylhexyl nitrate only Baseline
fuel - No. 2 Diesel 49.5 -- -- No. 2 diesel "2 + 2" 51.7 +2.2 -0.1
No. 2 diesel with 2.5 ml 100% 2- 51.8 +2.3 -- ethylhexyl nitrate
only
[0212] It has been observed that cetane may be synergistically
improved by combining di-tert-butyl peroxide with .beta.-carotene
in a cetane improver. An unexpected reduction in particulate matter
(PM) was also observed.
[0213] It may be preferred in certain embodiments of the cetane
improver to include as additional additives one or more plant oil
extracts such as oil extract of vetch and/or thermal stabilizers
such as jojoba oil, or to use as a cetane improving fuel additive
an additive combination suitable for use in gasoline, diesel, or
other hydrocarbon fuels as described in the preferred embodiments
herein.
Additive for Coal
[0214] A solution consisting of the following components was made
in the laboratory and applied to Coal received from China. 12 grams
of 30% .beta.-carotene in peanut oil was dissolved in 100
milliliters of toluene. In this same solution was dissolved 5 grams
of oil extract of vetch and 2 milliliters of jojoba oil. Toluene
was added to yield 4000 milliliters of solution. Six samples were
prepared. Three samples contained additized coal (Samples 4, 5, and
6). An additional three samples consisted of unadditized coal
(Samples 1, 2, and 3). The coal tested was from two different
places in China. Samples 1, 2, 4, and 5 originated from the Wan Li
coalfields and samples 3 and 6 originated from the Wu Da coalfields
in In ner Mongolia. The samples as received were mixed as
thoroughly as possible by hand and then 100 grams of this coal
material were separated from the mixed coal amount as a
representative sample. Those representative samples were then spray
treated at a treat rate corresponding to approximately 3.8 to 11.4
liters of the above-described liquid mixture per 1000 kg of coal.
These samples were then forwarded to Commercial Testing
Laboratories in San Pedro, Calif. for a short proximate analysis
test procedure. The test is an ASTM procedure for identifying the
physical characteristics of coal. The testing was performed on both
an "as received" basis and a "dry" basis. Table 23 provides test
results, including percent moisture, percent ash, percent sulfur,
and energy content in Btu/lb.
23 TABLE 23 Parameter As Received Dry Basis Sample 1-baseline (Wan
Li) % Moisture 31.06 -- % Ash 10.57 15.33 Btu/lb. 7519 10907 %
Sulfur 1.49 2.16 Sample 2-baseline (Wan Li) % Moisture 3.34 -- %
Ash 17.48 18.08 Btu/lb. 11685 12089 % Sulfur 3.97 4.11 Sample
3-baseline (Wu Da) % Moisture 31.12 -- % Ash 10.52 15.27 Btu/lb.
7555 10968 % Sulfur 1.65 2.39 Sample 4-treated (Wan Li) % Moisture
33.91 -- % Ash 9.46 14.31 Btu/lb. 11034 16696 % Sulfur 0.68 1.03
Sample 5-treated (Wan Li) % Moisture 16.89 -- % Ash 13.94 16.77
Btu/lb. 14123 16993 % Sulfur 2.58 3.11 Sample 6-treated (Wu Da) %
Moisture 35.85 -- % Ash 8.54 13.31 Btu/lb. 10879 16958 % Sulfur
0.49 0.76
[0215] Although the above additive levels may be preferred for
certain embodiments, in other embodiments it may be preferred to
have other additive levels. For example, the additive may be
present at about 1 ml or less up to about 20 liters or more per
1000 kg of unadditized coal, preferably at about 2 ml, 2.5 ml, 3
ml, 3.5 ml, 4 ml, 4.5 ml, 5 ml, 6 ml, 7 ml, 8 ml, 9 ml, 10 ml, 11
ml, 12 ml, 13 ml, 14 ml, 15 ml, 20 ml, 30 ml, 40 ml, 50 ml, 100 ml,
200 ml, 300 ml, 400 ml, 500 ml, 600 ml, 700 ml, 800 ml, 900 ml,
1liter, 2 liters, 3 liters, 4 liters, 5 liters, 6 liters, 7 liters,
8 liters, 9 liters, 10 liters, 11 liters, 12 liters, 13 liters, 14
liters, 15 liters, 16 liters, 17 liters, 18 liters, or 19 liters
per 1000 kg of unadditized coal.
Jet Fuel Smoke Point Improvement
[0216] The following formulation of .beta.-carotene, when added to
or mixed with a suitable carrier, can be added to or mixed with jet
fuel to increase the smoke point number of the fuel, as measured by
the ASTM D-1322 smoke point test. A common concern with jet fuel is
that a particular batch may be out of compliance with the stringent
jet fuel specifications. By adding .beta.-carotene to the jet fuel,
the smoke point of the jet fuel may be improved without the need
for additional refinery processing.
[0217] The .beta.-carotene is preferably added to the fuel in the
form of an additive mixture containing 4 grams of synthetic
.beta.-carotene or 10 grams of natural .beta.-carotene, 3000 ml jet
fuel, and sufficient toluene to yield 3785 ml additive mixture. The
additive mixture is typically prepared by mixing .beta.-carotene in
a suitable volume of toluene or another carrier fluid under an
inert atmosphere, such as a nitrogen atmosphere, then adding the
.beta.-carotene mixture to a base jet fuel. It is preferred that
the additive mixture of .beta.-carotene be maintained under inert
atmosphere until use.
[0218] The additive mixture is typically added to the jet fuel at a
treat rate of 2 ml to 6 ml per 3785 ml jet fuel. Typical increases
in smoke point observed are from approximately 2 millimeters when
using 2 ml additive per 3785 ml jet fuel to 6 millimeters when
using 6 ml additive per 3785 ml jet fuel.
[0219] Smoke point is one of the major ASTM test procedures
utilized by refineries to determine if the jet fuel meets
specification. The addition of the additive to the jet fuel
increases the smoke point of the jet fuel such that it meets
specification. This allows the jet fuel to pass a final inspection
without first undergoing more severe refinery processing, such as
processing to remove aromatics from the jet fuel, thereby allowing
the refinery to produce jet fuel in compliance with ASTM
regulations in a cost effective manner when the smoke point exceeds
tolerance. The alternative is for the refinery to send the Jet back
into processing, a more expensive alternative.
[0220] The following ASTM D-1322 smoke point test results were
obtained for neat standard jet fuel and the same fuel treated with
the additive mixture described above at various treat rates.
Substantial increases in smoke point were observed for the treated
jet fuels. Test results suggest that a maximum increase in smoke
point may be obtained at a treat rate of 6 ml per 3785 ml treated
jet fuel, with no substantial additional increase in smoke point
observed at higher treat rates.
24 TABLE 24 Treat Rate (per 3785 ml Smoke Change Over Base Fuel
additized fuel) Point Baseline A 0 20.0 mm -- A 1 ml 23.5 mm +3.5 B
0 19.5 mm -- B 1 ml 21.0 mm +1.5 C 0 20.0 mm -- C 0 20.0 mm -- D 4
ml 24.5 mm +4.5 D 6 ml 25.0 mm +5.0 E 4 ml 24.5 mm +4.5 E 6 ml 25.0
mm +5.0 F 0 20.0 mm -- F 0 20.0 mm -- G 8 ml 25.0 mm +5.0 G 8 ml
25.0 mm +5.0 H 8 ml 25.0 mm +5.0 H 8 ml 25.0 mm +5.0
[0221] While the above additive levels may be preferred for certain
jet fuel formulations, in various other jet fuel formulations other
additive levels may be preferred, for example, the additive may be
present at about 0.1 ml or less up to about 20 ml or more,
preferably at about 0.5, 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7,
8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, or 19 ml per 3785 ml of
additized jet fuel. Moreover, it may be preferred in certain
embodiments to include as additional additives one or more plant
oil extracts such as oil extract of vetch and/or thermal
stabilizers such as jojoba oil, or to use as a jet fuel additive an
additive combination suitable for use in gasoline, diesel, or other
hydrocarbon fuels as described in the preferred embodiments
herein.
Emissions Testing--Gasoline Vehicles
[0222] "Cold-Start and Hot-Start" emissions tests of a European
CEC-RF-08-A-85 Reference fuel (both additized and unadditized)
using two different models of PROTON WIRA vehicles were conducted.
The tests were conducted for Malaysia Canada Development
Corporation Sdn. Bhd. (MCDC) with close supervision by Standards
and Industrial Research Institute of Malaysia (SIRIM). The tests
were conducted at the PETRONAS Research & Scientific Services
Sdn. Bhd. (PRSS) Vehicle Emissions Testing Laboratory located in
Section 27, Selangor Darul Ehsan, Shah Alam, Malaysia. A schematic
illustrating the layout of the vehicle emissions testing equipment
is provided in FIG. 3.
[0223] The test vehicles included two different models of PROTON
WIRA, namely PROTON WIRA 1.6XLi Aeroback-Multipoint injection
(Automatic) and PROTON WIRA 1.6XLi Sedan-Multipoint injection
equipped with catalytic converter (Automatic) gasoline vehicles.
Each test vehicle was tested at cold and hot starting using
untreated and treated reference fuel. The baseline emissions of
each vehicle were established based on the untreated reference fuel
emissions measurement.
[0224] The testing program for the emissions evaluation was carried
out according to the following test modes provided in Table 25.
25TABLE 25 TEST VEHICLE TEST MODES Test vehicle 1 Cold-start
emissions test using untreated (Multipoint Reference fuel
injection) Cold-start emissions test using Reference fuel treated
with CEM Catalyst Fuel System. Test vehicle 2 Hot-start emissions
test using untreated (Multipoint Reference fuel. injection equipped
Hot-start emissions test using Reference with catalytic fuel
treated with CEM Catalyst Fuel System. converter)
[0225] In the testing program, the latest European Emissions
Standard ECE R15-04 plus EUDC test cycle were used to establish the
mass of each exhaust component emitted during the test. The ECE
R15-04 plus EUDC test cycle were used in the evaluation since there
is an indication by the Malaysian government to adopt the European
Emissions Standard for Malaysia. A diagram illustrating the
European Emissions Standard ECE R15-04 plus EUDC Emissions Test
Cycle is provided in FIG. 4.
[0226] The European Emissions Standard test cycle is made up of two
parts. Part One is define as an Urban test cycle, which represent
city-center driving, whereas Part Two of the emissions test cycle
is known as the Extra-urban driving cycle. The total cumulative
time and vehicle travelling distance for complete Part One and Part
Two test cycles were 1,180 seconds and 11,007 km, respectively.
[0227] The vehicle emissions test procedures were divided into
three distinct segments. Each test vehicle was subjected to the
following sequence:
[0228] Pre-Condition Checks--Prior to emissions testing, the
pre-condition checks and their "state of tune" of the test vehicle
were assessed. The ignition system (spark plugs, high-tension
leads, and the like), ignition timing, engine cooling system and
air filter cleaner element conditions were checked and replaced
when necessary. This was done in order to ensure that the vehicle
was in good conditions and meet the requirements of the engine
manufacturer. The results of the Pre-Condition Checks of the two
vehicles are as shown in Table 26 below.
26TABLE 26 Engine Pre-Condition Checks Vehicle 1 Vehicle 2 1
BATTERY/STARTER 1.1 Battery voltage Pass Pass 1.2 Cranking volts
Pass Pass 1.3 Cranking speed Pass Pass 2. COIL/LEADS/PLUGS 2.1
Sparkplugs Pass Pass 2.2 High tension lead resistance Pass Pass
condition 3. FUEL INJECTION 3.1 Air filter check Pass Pass 3.2 Fuel
filter check Pass Pass 3.3 Injectors condition Pass Pass 3.4
Injectors operation Pass Pass 3.5 Throttle shaft Pass Pass 4.
DISTRIBUTOR 4.1 Static timing Pass Pass 4.2 Rotor condition Pass
Pass 4.3 Cap condition Pass Pass 4.4 Electronic ignition condition
Pass Pass 4.5 Vacuum advance operation Pass Pass 5. ENGINE COOLING
SYSTEM Pass Pass REMARKS GOOD GOOD CONDITION CONDITION
[0229] Soaking of Test Vehicle--The test vehicle was then allowed
to soak in a test laboratory for at least six hours at a test
temperature of 20 to 30.degree. C. This was done in the preparation
of a so-called "cold-start" test.
[0230] Exhaust Emissions Tests--The test vehicle was then started
and allowed to idle for 40 seconds. The vehicle was then driven in
accordance to ECE RI 5-04 plus EUDC on the chassis dynamometer
which has been pre-set to a "fixed load curve" to produce level
road load conditions (simulating the wind resistance, frictional
forces, etc. as experienced by the car on the road). During the
test period, the diluted exhaust gas was continuously sampled at a
constant rate. This diluted exhaust sample and a concurrent sample
of the dilution air were collected into sampling bags for the
subsequent analysis at an analytical bench.
[0231] In addition, the hot-start emissions test was also conducted
(engine at normal operating temperature during starting) upon
completion of cold-start emissions test. measured emissions
included carbon monoxide (g/km); carbon dioxide (g/cm); total
ocarbon (g/km); and oxides of nitrogen (g/km).
[0232] The vehicle exhaust gas emissions test was conducted in a
Vehicle Emissions ing Laboratory. The laboratory contained the
following equipment:
[0233] HORIBA MEXA 9000 SERIES Exhaust Gas Analyzers and Sampling
System--This equipment was used to sample and measure the levels of
exhaust gases emitted the test vehicles. The system is designed to
accommodate the necessary analyzers measuring the total
hydrocarbons (THC), carbon monoxide (CO), carbon dioxide
(CO.sub.2), and oxides of nitrogen (NO.sub.x). The THC was analyzed
by flame ionization ctor (FID), CO and CO.sub.2, by non-dispersive
infrared (NDIR) analyzer, and NO.sub.x by iluminescent (CL)
analyzer.
[0234] SYSTEM III CLAYTON DC80 Chassis Dynamometer--The chassis
mometer was used to simulate road load driving condition by setting
the opriate inertia and load for the test vehicle reference weight.
This simulation valent inertia weight method is permitted by the
Regulation ECE-15.
[0235] The properties of the Standard European Reference Fuel
CEC-RF-08-A-85 used baseline fuel in the testing is provided in the
following table.
27TABLE 27 Specifications of the European CEC-08-A-85 Reference
Fuel. CEC-08-A-86 REFERENCE FUEL ASTM FUEL SPECIFICATION NO.
PROPERTIES METHOD SAMPLE Minimum Maximum 1 Research Octane D 2699
97.8 95.0 Number (RON) 2 Motor Octane D 2700 87.4 85.0 Number (MON)
3 Density at 15.degree. C., D 1298 752.2 748.0 762.0 kg/m.sup.3 4
Reid Vapor D 323 0.63 0.56 0.64 Pressure, bar 5 Distillation: D 86
Initial boiling 31 24 40 point, .degree. C. 10% vol. point, 43 42
58 .degree. C. 50% vol. point, 106 90 110 .degree. C. 90% vol.
point, 260 155 180 .degree. C. Final boiling 202 190 215 point,
.degree. C. 6 Residue, % vol. D 86 0.5 2.0 7 Hydrocarbon by PONA
analysis: Olefin, % vol. 5.5 20 Aromatic, % vol. 34.3 45 Saturates,
% vol. 60.2 balance 8 Oxidation D 525 >1000 480 Stability, min 9
Existent Gum, D 381 0.2 4.0 mg/100 ml 10 Sulfur Content, % D 1266
0.0080 0.04 wt. 11 Copper Corrosion D 130 1 a 1 at 50.degree. C. 12
Lead Content, g/l D 3237 <0.0025 0.0050 13 Phosphorous D 3231
<0.0002 0.0013 Content, g/l
[0236] The additive formulations tested included the OR-1 Mexico
low altitude formulation described above, additionally containing 2
milliliters of polyisobutylene per gallon of gasoline treated.
Details of the test vehicles used in the program are provided in
Table 28.
28TABLE 28 NO. SPECIFICATIONS VEHICLE 1 VEHICLE 2 1 Model PROTON
WIRA PROTON WIRA 2 Vehicle Type Hatch-back Sedan 3 Chassis No.
PL1C98LRRSB762361 M-1_003F3 4 Registration No. WDY 9438 W 1267 A 5
Drive Wheels Front Front 6 Engine Engine Model 4G92 4G92 Engine No.
4G29P CW 8386 4 G 92 AM9953 Type 4-cylinder-in-line
4-cylinder-in-line Capacity 1600 c.c. 1600 c.c. Fuel System
Injection Injection - cat. con. Ignition System Electronic
Electronic 7 Transmission Gearbox Type Automatic Automatic No. of
Gear Ratio Five Five
[0237] Cold-Start Emissions Test Results are provided in Table
29.
29TABLE 29 EXHAUST GAS EMISSIONS (g/km) TEST TEST ODOMETER VEHICLE
FUEL (km) CO CO.sub.2 THC NO.sub.x Vehicle 1 Baseline 31414 1.90
159 1.180 3.221 CEM 31437 1.48 154 1.133 3.089 Catalyst 1
Percentage Different -22.11 -3.14 -3.98 -4.10 Vehicle 2 Baseline
94687 3.73 163 0.773 1.390 CEM 94698 3.23 163 0.778 1.368 Catalyst
Percentage Different -13.40 n/c n/c -1.58
[0238] Hot-Start Emissions Test results are provided in Table
30.
30TABLE 30 EXHAUST GAS EMISSIONS (g/km) ODOM- TEST TEST ETER
VEHICLE FUEL (km) CO CO.sub.2 THC NO.sub.x Vehicle 1 Baseline 31459
1.39 145 1.058 3.230 CEM 31448 1.10 142 1.022 2.917 Catalyst
Percentage Different -20.86 -2.07 -3.40 -9.69 Vehicle 2 Baseline
94735 3.93 144 0.615 1.322 CEM 94724 1.81 146 0.403 1.026 Catalyst
Percentage Different -53.94 +1.39 -34.47 -22.39
[0239] The emissions data gathered were obtained on European
CEC-RF-08-A-85 Reference Fuel tested using only one PROTON WIRA
1.6XLi Aeroback-Multipoint injection (Automatic) and PROTON WIRA
1.6XLi Sedan-Multipoint injection equipped with catalytic converter
(Automatic). The overall emissions results show that there was a
reduction in both the cold-start and hot-start emissions of the
vehicles. For both vehicles, emissions reductions ranging up to 22%
for CO, 3% for CO.sub.2, 4% for THC, and 4% for NO.sub.x were
observed in cold-start emissions testing whereas for the hot-start,
reductions ranging up to 54% for CO, 2% for CO.sub.2, 34% for THC,
and 22% for NO.sub.x, were recorded. No change in CO.sub.2
emissions was observed at the cold-start of PROTON WIRA 1.6XLi
Multipoint injection fitted with a catalytic converter. However,
there was a slight increased of CO.sub.2 (1.4%) during the
hot-start. On the multipoint injection vehicle, no change in
CO.sub.2 emissions was observed either at the cold or
hot-start.
Emissions testing--Gasoline Vehicles
[0240] The Colorado School of Mines/Colorado Institute for Fuels
and High Altitude Engine Research validated test results and
confirmed performance levels for a fuel additive device and liquid
fuel additive as described above.
[0241] The analysis was based on the results of approximately sixty
Hot 505 runs, conducted on a 1989 Honda Accord and a 1990 Ford
Taurus, at Environmental Testing Corporation in Orange, Calif. The
Honda had approximately 101,000 odometer miles at the start of the
testing and had a carburetor fuel system. The Ford had
approximately 64,000 odometer miles at the start of the testing and
had a port fuel injection fuel system. Results for emissions of
NO.sub.x, CO, CO.sub.2, non-methane hydrocarbon (NMHC), as well as
fuel economy in miles per gallon (mpg) were analyzed.
[0242] Emissions and fuel economy testing was performed at
Environmental Testing Corporation (ETC) in Orange, Calif. The data
set consists of a series of emissions and fuel economy results from
the Hot 505 Phase of the Federal Test Procedure. The Hot 505 test
is so called because it lasts exactly 505 seconds, and is performed
on a vehicle at peak operating temperature with the catalytic
converter operating at optimum. Immediately prior to the test, the
vehicle was run at 50 mph for 5 minutes, brought to a stop, and
idled for 20 seconds. Samples were continuously acquired through a
constant volume sampler, and stored in a tedlar bag for analysis
immediately at the end of the test. Five gas analyzers were used to
determine the concentration of the sample: total hydrocarbon (THC),
carbon monoxide (CO), oxides of nitrogen (NO.sub.x), carbon dioxide
(CO.sub.2), and methane (CH.sub.4). The fuel economy, or miles per
gallon (mpg), is calculated from the concentration of CO.sub.2. The
concentration of regulated emission of non-methane hydrocarbon
(NMHC) is calculated by difference from the concentration of THC
and CH.sub.4. Calibrations on all instruments, using the same set
of 1% NIST traceable span gases, were performed every 30 days as
well as weekly diagnostic tests. All reported emissions values were
good to within an accuracy of .+-.5%.
[0243] All the tests were performed with the same chassis
dynamometer and the same emission system, which was set up the same
way for each run as prescribed by CARB and EPA (as described in the
Code of Federal Regulations or CFR) procedures. This included
checking the tire pressure of the car and all appropriate settings
of the emission system. A control vehicle was not used to verify
that there was no drift in the measurements. No precautions were
taken to randomize the tests, in part because it was believed that
the additive may have a "memory." That is, the effect of the
additive may be observed for some time after removal of the device
from the vehicle or additive from the fuel. No observations on
ping, knock, misfire, and the like, either with or without the
device installed, were recorded.
[0244] The Base Fuel--The base fuel used was indolene from the same
lot. The octane number of the indolene used in this study was 92.1
([R+M]/2). The fuel in the vehicle was replaced with fresh indolene
after each series. ETC took custody of all the cars used throughout
this set of tests, and had responsibility for installing the
devices and adding the liquid additive. The same driver was used in
every test. The only driver change occurred when the vehicle was
driven for mileage accumulation to remove any additive "memory" and
return to baseline (so-called "deconditioning"). Mileage
accumulation utilized a predetermined route. No maintenance,
including oil changes, was performed on the vehicles during the
test program.
[0245] The Fuel Additive Device--In certain tests the base fuel was
additized using a fuel additive device. The device is manufactured
much like an in-line fuel filter. The housing is built of stainless
steel with a small mesh wire cage fitted just inside the middle of
the device. Different raw material are loaded into the wire cage,
the cage is fitted inside of a stainless steel housing, and then a
cap is electron beam welded to the housing to form one unit. The
fuel additive device is then placed into the fuel line after the
gasoline tank but before the fuel rail or carburetor, and
immediately before the fuel filter. The flow pattern of gasoline is
from the tank through the fuel additive device, through the fuel
filter, into the fuel rail or carburetor, and then the fuel is
atomized into the combustion chamber. Each time fuel passes through
the device, a tiny amount of raw materials solubilize into the
fuel.
[0246] The amount of mileage that may be accumulated on a vehicle
before exhausting the raw materials in the fuel additive device may
be calculated based on the gross amount of raw material loaded into
the fuel additive device. For example, a fuel additive device with
54 grams of total raw material is typically able to last 10,000
miles when retrofitted onto a carburetor gasoline motor vehicle.
When a fuel additive device containing 54 grams of raw material is
retrofitted onto a fuel-injected car with recirculation of the
fuel, the fuel additive device will typically last for over 6,000
miles.
[0247] The amount of mileage that may be accumulated before the
additive is exhausted may be determined by a number of factors,
including, but not limited to, the number of holes dilled into the
stem pipe or the middle pipe that extends the length of the device.
The middle pipe is approximately 8.7 cm long with a 1.3 cm outside
diameter. Each pipe is drilled with one or more holes having a
diameter of 0.08 cm. Fuel additive devices were tested with one
hole, two holes, three holes, and more (up to nine holes total) in
the middle pipe. The preferred combination of emission reduction,
improved fuel economy, and accumulated miles was observed for two
or three holes having a diameter of 0.08 cm drilled into the pipe.
All of the holes are preferably drilled into only one side of the
pipe and open only from that side of the pipe to the middle of the
pipe. Table 31 provides a description of each of the fuel additive
devices tested.
31TABLE 31 Device # Weight (g) Additive 1 25 grams Oil extracted
vetch 0.55 grams Butylated hydroxytoluene (BHT) 0.75 grams Curcumin
2 25 grams Oil extracted hops 1.0 grams Vegetable Carotenoids (VC)
(a mixture of .alpha.-carotene, additional carotenoids from D.
salina algae: xeaxanthin, cyptoxanthin, lycopene and lutein. lutein
from marigolds, lycopene from tomatoes, broccoli concentrate,
spinach concentrate, tomato concentrate, kale powder, cabbage
powders and Brussels sprouts powder). 1.0 grams BHT 3 25 grams Oil
extracted hops 1.5 grams VC 1.0 grams BHT 4 25 grams Oil extracted
hops 1.5 grams VC 1.5 grams BHT 5 25 grams Oil extracted hops 2.0
grams VC 1.5 grams BHT 6 25 grams Oil extracted vetch 2.0 grams VC
2.0 grams BHT 7 25 grams Oil extracted vetch 2.0 grams VC 2.0 grams
BHT 1.0 gram Curcumin
[0248] The Liquid Fuel Additive--The liquid fuel additive included
4 grams of .beta.-carotene, 2 grams of BHT, 6 milliliters of jojoba
oil, and 19.21 grams of oil extracted vetch and/or oil extracted
hops. The components were dissolved in toluene to provide 3785
milliliters of concentrated solution. 4 milliliters of this
concentrated solution were added to the base fuel.
[0249] The Test Procedure--The test procedure was generally as
follows: initial testing to measure and verify repeatability of
baseline emissions and fuel economy; installation of the fuel
additive device; on road conditioning of approximately 30 miles
before dynamometer testing; a series of independent Hot 505 test
runs; removal of the fuel additive device from the vehicle, removal
of the fuel from the fuel tank and replacement with fresh fuel; on
road mileage accumulation of approximately 50 to 200 miles for
deconditioning; and testing to verify that emissions and fuel
economy had returned to baseline.
[0250] The additive (either in the fuel additive device or in the
liquid additive) for each test was of the same formulation and from
the same batch. The fuel additive device changes for the solid
additive were mechanical in nature and only affected the dosage
rate, not the composition of the additive. Other testing indicated
that a single vehicle equipped with an additive delivery device
consumed 41 g of solid additive over 1000 miles of driving at a
fuel economy of 15.4 mpg. Based on these data, the dosage of
additive in the fuel by the fuel additive device to that vehicle
was estimated to average approximately 250 ppm. Based on this data,
it can be concluded that the additive concentration in the tests
reported was in the 100-1000 ppm range. The liquid additive was
added at a level of 6 ml for each gallon of gasoline, or
approximately 15 ppm.
[0251] Data were analyzed for a 1990 Ford Taurus (3.0 liter, fuel
injected, 64,000 miles) and a 1989 Honda Accord (2.0 liter, engine
carburetor, 101,000 miles). The Hot 505 test results are presented
as a function of odometer mileage. Runs were conducted without the
fuel additive device, with the fuel additive device installed, and
with the liquid fuel additive as noted. Results for NMHC, CO, NO,
and fuel economy are also provided.
[0252] Results for 1990 Ford Taurus--FIGS. 5 through 9 present
results for NO.sub.x, CO, NMHC, CO.sub.2, (g/mi.) and fuel economy
(mpg), respectively, as a function of odometer mileage. Three
baseline runs were performed, followed by five runs with the
additive delivery device installed, roughly 250 miles of
"deconditioning" without the device, three additional baselines,
then five runs using the liquid fuel additive. The Ford Taurus data
suggests that both the device and the liquid fuel additive reduce
pollutant emissions and increase fuel economy. Runs with the device
suggest an increase in the effect with mileage. The Ford Taurus had
a common rail fuel injection system. Thus, additive put into the
fuel by the additive delivery device was recirculated back to the
fuel tank. It is therefore possible that the additive concentration
in the fuel continuously increased during the test sequence for
this vehicle.
[0253] Results for 1989 Honda Accord--FIGS. 10 through 14 present
results for NO.sub.x, CO, NMHC, CO.sub.2, (g/mi.) and fuel economy
(mpg), respectively, as a function of odometer mileage. Three
baseline runs were conducted, followed by a series of runs with the
fuel additive device installed. In these runs, different devices
were employed every few runs. The device numbers refer to the
different fuel additive devices in Table 31. Following a sequence
with the fuel additive device, five baseline runs were conducted
followed by roughly 200 miles of deconditioning, then five baseline
runs, roughly 200 miles of additional deconditioning, six
additional baseline runs, then a series of runs with the liquid
fuel additive. The data suggest a reduction in NO.sub.x emissions
relative to the first set of baseline runs but not relative to all
of the baseline runs taken together. Emissions of other pollutants
do not appear to decrease for the device. Emissions of NO.sub.x,
however, apparently continued to decrease after removal of the
device. The liquid additive did not appear to have a significant
effect. Emissions from the Honda Accord appear to be much more
variable than those from the Ford Taurus.
[0254] The test data was subject to statistical analysis to
determine whether effects observed were statistically significant.
The approach to analyzing the test results taken was to assume that
all baseline runs were true baselines and that all runs with the
fuel additive device or liquid additive were representative of the
effect. This assumes that the variation in baseline runs was random
and simply a measurement of experimental error. This same
assumption applies both to runs with the fuel additive device and
the liquid additive. So-called "memory" effects, described above,
were assumed to be unimportant.
[0255] In this approach, all baseline run emissions and fuel
economy values were averaged and compared to averages obtained with
the fuel additive device or liquid additive. These averages were
compared for the Ford and Honda in Tables 32 and 33, respectively.
Also reported with the average values is the percent change for
operating with the fuel additive device or liquid additive relative
to the baseline. The data were used to statistically test the
hypothesis that there was no difference between emissions and fuel
economy for the baseline runs and runs with the device or additive
(the null hypothesis). The tables report the results of this test
as a probability that the null hypothesis is true, or P-value. A
small P-value indicates that the null hypothesis should be rejected
and that there was a significant effect.
[0256] Examination of the results indicates that, under the
assumptions of this analysis, there is little probability that the
null hypothesis of no effect is true for the device. Thus, the
device appears to result in reduced emissions of CO, CO.sub.2, and
NMHC, and improved fuel economy for both vehicles. For NO.sub.x,
the effect of the device was different with a decrease in the Ford
but an increase in emissions for the Honda. For the fuel additive
in the Ford Taurus there appears to be a real effect. For the fuel
additive in the Honda, there is a significant probability that the
liquid fuel additive had no effect. It is important to note that we
have no information that allows us to conclusively assign the
changes observed to the fuel additive. Insufficient tests were
conducted and insufficient control data are available to allow a
conclusion regarding cause and effect.
32TABLE 32 Ford Basic Statistical Analysis NO.sub.x, g/mi. CO,
g/mi. NMHC, g/mi. CO.sub.2, g/mi. Mpg baseline 0.318 1.418 0.064
381.4 23.13 average baseline 0.022 0.122 0.006 2.6 0.15 standard
deviation w/device 0.231 1.201 0.055 363.6 24.30 average w/device
0.048 0.186 0.003 11.1 0.75 standard deviation w/device -27.3 -15.3
-14.1 -4.7% +5.0 % change P-value 0.003 0.04 0.009 0.004 0.005
Estimated -12.2% -2.2% -9.4% -1.8% +1.8% Minimum Effect w/liquid
0.208 1.191 0.061 373.4 23.65 average w/liquid 0.010 0.112 0.003
1.3 0.08 standard deviation w/liquid -34.6 -16.0 -4.7 2.1% 2.2 %
change P-value <0.001 <0.001 0.21 <0.001 <0.001
[0257]
33TABLE 33 Honda Basic Statistical Analysis NO.sub.x, g/mi. CO,
g/mi. NMHC, g/mi. CO.sub.2, g/mi. Mpg baseline 0.577 1.776 0.033
314.4 27.98 average baseline 0.070 0.309 0.005 5.1 0.44 standard
deviation w/device 0.610 1.293 0.027 310.5 28.41 average w/device
0.029 0.151 0.004 6.6 0.61 standard deviation w/device +5.7 -27.2
-18.2 -1.2% +1.5 % change P-value 0.049 <0.001 <0.001
<0.001 0.017 Estimated +0.7% -18.7% -6.0% 0 0 Minimum Effect
w/liquid 0.588 1.640 0.030 312.4 28.17 average w/liquid 0.023 0.165
0.003 2.6 0.23 standard deviation w/liquid 1.9 -7.6 -9.1 25.2% 0.7
% change P-value 0.65 0.21 0.099 0.006 0.21
[0258] The analysis above is based on the assumption that variation
in the baseline runs is random. That is, there is no "memory"
effect and when the device or liquid additive is removed the engine
quickly returns to baseline performance. To test this assumption,
we have performed a Shewhart control plot statistical test for
randomness, or equivalently, a test to see if the baseline runs are
all sampled from the same population. The results are provided in
FIGS. 15 through 19. Insufficient data are available for the Ford
Taurus to perform this test so it was performed on the Honda Accord
only. Points which fall within the dashed lines in the plots (3
standard deviations or 3 sigma) have a greater than 99% probability
of having been sampled from the same population.
[0259] For NO.sub.x the initial baseline point is outside the
three-sigma lines and the data are not randomly distributed around
the average. Based on the Shewhart control plot, the NO.sub.x
baseline points collected prior to testing with the device were
excluded from the statistical analysis. For CO, NMHC, and fuel
economy, the data are consistent with the three-sigma criterion and
show a random variation about the mean. It can therefore be
concluded that all baseline runs are from the same population and
there is no "memory" of the device or additive. Based on all of the
data, we suspect an error in the NO.sub.x measurements rather than
"memory" of the device in the engine. The statistical analysis
shown in Table 34 for the Honda NO.sub.x, was repeated without the
first three baseline runs and results are reported in Table 34.
Rejection of these three points has no effect on the overall
conclusions of the analysis.
34TABLE 34 Honda NO.sub.x data without the first three baselines
NO.sub.x, g/mi baseline average 0.554 baseline standard deviation
0.051 w/device average 0.610 w/device standard deviation 0.029
w/device % change +10.1 P-value <0.01 Estimated Minimum Effect
+4.9% w/liquid average 0.588 w/liquid standard deviation 0.023
w/liquid % change 3.4 P-value 0.06
[0260] It is difficult to draw a conclusion regarding the average
emissions reduction or fuel economy increase that might be expected
using the additives of preferred embodiments because results for
only two vehicles have been analyzed. However, the minimum
improvement that might be realized may be estimated. The average
emissions reduction plus one standard deviation, or the average
fuel economy increase less one standard deviation is an estimate of
the minimum improvement expected for the fulel additive device.
These results are reported in Tables 32, 33, and 34 as estimated
minimum effect. In some cases, the possibility of zero effect was
encompassed by one standard deviation (namely, for the Honda
Accord) and for these the estimated minimum effect is reported as
zero. The average minimum effect for the two vehicles may be used
as a global estimate, although there is considerable uncertainty in
this approach given that it is only based on two vehicles. The
average minimum emissions reduction and fuel economy improvements
expected are: -10.5% for CO; -7.7% for NMHC; -1% for CO.sub.2; and
+1% for fuel economy.
[0261] As noted, the results indicate a significant positive effect
of the additives of preferred embodiments on emissions of CO,
CO.sub.2, NMHC, and on fuel economy. The situation is ambiguous for
NO.sub.x. Given the small number of vehicles and the .+-.20%
variation typically observed for light-duty vehicle emissions
testing, the difference in emissions may not have been caused by
the additive. To show cause and effect requires repeated cycles
with and without the fuel additive device installed and requires
better measures of day-to-day variability (for example, the use of
a control vehicle). Testing of two different vehicle technologies
(carburetor and fuel injection) provides a better prediction, but
two vehicles are too few to draw definitive conclusions. For
example in the case of NO.sub.x, the fact that one vehicle
exhibited a decrease while the other exhibited an increase could be
random error or could be caused by differences in fuel system
technology.
[0262] Although only two vehicles were tested, it can be concluded
that the fuel additive device reduces CO and NMHC, and increases
fuel economy. A reduction in NO.sub.x may be observed, but the
results are ambiguous because the Honda data exhibits significant
drift. Clearly additional testing may be useful in quantifying the
magnitude of the emissions and fuel economy effects as well as
determining how these effects are altered by additive dosage level.
It is noted that fuel economy was observed to increase while at the
same time NO.sub.x, decreased. This may be an effect of the
additive, but could also result from human error or experimental
factors. Such factors may include the dynamometer inertial load
being incorrectly set, use of a different driver was used or
driving the test cycle differently, differences in ambient air
temperature or humidity, incorrect application of the humidity
correction, or instrumentation malf unction.
[0263] Two observations suggest the mechanism of action of the fuel
additive. First, fuel economy improves and second, the effect is
immediate. This is typical of a driveability improver additive,
such as an octane improver. Thus, the data suggest that the
additive is somehow altering the combustion process, perhaps by
reducing ping, knock, misfire, or similar effects. However, no
observations on driveability differences were reported. This
conclusion is supported by independent measurements of octane
number. These data suggest an increase of 2 octane number units for
1 ml/gallon of additive (roughly 2-3 ppm). However, insufficient
information is available to evaluate the quality of the octane
number measurements.
[0264] It is unlikely that the additive impacts deposits via
detergent or dispersant action, however no inspection or analysis
of the fuel system or combustion chamber was conducted to confirm
this. It is also unlikely that the fuel additive device or additive
impacts the exhaust catalyst. The catalyst is very hot in the Hot
505 runs and the additive is primarily organic. Thus, any additive
surviving the combustion process should simply be burned by the
catalyst.
[0265] Statistical analysis of the results indicates statistically
significant differences in emissions and fuel economy, compared to
baseline runs, for both the fuel additive device and the liquid
fuel additive. For the fuel additive device, a significant decrease
in emissions of CO, CO.sub.2, and NMHC was observed along with an
increase in fuel economy. A reduction in NO.sub.x emissions may
also be observed. The two vehicles tested have different fuel
supply system technologies and exhibit different responses, namely,
different changes in emissions or fuel economy. Thus, a universal
conclusion regarding the magnitude of emissions reduction and fuel
economy increase cannot be made. Similar conclusions can be drawn
for the liquid fuel additive although the magnitude of the effects
is smaller and the uncertainty in the results is greater.
Statistical analysis of the data indicates that all baseline runs
come from the same population. This means that there is no "memory"
effect and the vehicle returns rapidly to baseline upon removal of
the device. It is believed that the additive dosage level in tests
using the fuel additive device was in the 100 to 1000 ppm range.
The observed effects, immediate response, lack of a "memory"
effect, and dosage range all suggest that the additives of
preferred embodiments act as a driveability improver with a direct
effect on the combustion process. The data subjected to statistical
analysis are presented in Table 35.
35TABLE 35 Odometer Fuel Test miles Barometer Dry T Wet T Start HC
CO CO.sub.2 NO.sub.x CH.sub.4 NMHC Econ No. Vehicle Fuel at start
in. Hg .degree. F. .degree. F. Time Distance g/mi g/mi g/mi g/mi
g/mi g/mi MPG 2254 Honda base 101158 29.76 77.86 64.78 8/27/9 3.57
0.086 2.17 324.2 0.693 0.045 0.042 27.09 baseline 11:19 2255 Honda
base 101167 29.71 78.62 66.56 8/27/9 3.58 0.067 1.127 320.2 0.698
0.041 0.026 27.56 baseline 11:47 2256 Honda base 101175 29.72 77.92
66.59 8/27/9 3.58 0.073 1.513 319.6 0.685 0.043 0.03 27.56 baseline
12:14 2265 Honda base 101186 29.74 77.67 66.36 8/28/9 3.56 0.076
1.482 323 0.637 0.043 0.033 27.28 w/device 12:06 2266 Honda base
101195 29.72 77.34 66.38 8/28/9 3.57 0.072 1.39 317.8 0.653 0.043
0.029 27.74 w/device 12:36 2267 Honda base 101204 29.72 78.43 66.99
8/28/9 3.57 0.073 1.646 316.2 0.655 0.044 0.029 27.84 w/device
13:11 2268 Honda base 101213 29.71 78.96 67.48 8/28/9 3.58 0.06
1.003 318.1 0.66 0.04 0.02 27.76 w/device 13:30 2274 Honda base
101229 29.74 75.74 66.01 8/29/9 3.57 0.068 1.43 315.6 0.637 0.04
0.028 27.92 w/device 10:49 #2 2275 Honda base 101238 29.73 75.43
65.02 8/29/9 3.58 0.067 1.253 316.3 0.594 0.04 0.027 27.88 w/device
11:17 #2 2277 Honda base 101247 29.74 75.05 63.96 8/29/9 3.57 0.072
1.399 314.2 0.652 0.041 0.031 28.05 w/device 12:03 #2 2278 Honda
base 101264 29.73 75.08 63.64 8/29/9 3.57 0.07 1.459 314.6 0.601
0.039 0.03 28.01 w/device 13:24 #3 2279 Honda base 101273 29.69
76.18 64.28 8/29/9 3.57 0.067 1.357 315.6 0.597 0.04 0.027 27.93
w/device 13:54 #3 2280 Honda base 101282 29.68 76.63 64.66 8/29/9
3.57 0.064 1.249 311.9 0.612 0.039 0.025 28.28 w/device 14:22 #3
2281 Honda base 101297 29.68 76.72 64.44 8/29/9 3.57 0.063 1.272
311.1 0.605 0.04 0.022 28.35 w/device 15:45 #4 2282 Honda base
101306 29.67 76.85 64.52 8/29/9 3.57 0.063 1.26 310.3 0.613 0.04
0.023 28.42 w/device 16:12 #4 2283 Honda base 101315 29.65 77.08
64.58 8/29/9 3.57 0.063 1.413 313.2 0.588 0.04 0.023 28.14 w/device
16:40 #4 2284 Honda base 101330 29.75 74.45 62.35 8/30/9 3.58 0.072
1.26 304.8 0.611 0.042 0.031 28.92 w/device 10:14 #5 2285 Honda
base 101339 29.73 74.83 63.99 8/30/9 3.58 0.063 1.026 304.7 0.599
0.04 0.024 28.97 w/device 10:40 #5 2286 Honda base 101348 29.72
74.81 63.82 8/30/9 3.58 0.066 1.159 301.1 0.584 0.041 0.025 29.3
w/device 11:08 #5 2288 Honda base 101357 29.72 75.63 63.91 8/30/9
3.58 0.064 1.343 301.8 0.55 0.038 0.026 29.2 w/device 12:03 #6 2289
Honda base 101372 29.68 76.11 64.25 8/30/9 3.58 0.063 1.174 301.3
0.598 0.04 0.024 29.28 w/device 12:27 #6 2290 Honda base 101381
29.67 75.78 64.32 8/30/9 3.58 0.073 1.148 301.5 0.627 0.038 0.035
29.26 device 12:54 #6 2291 Honda base 101392 29.66 76.87 65.63
8/30/9 3.59 0.06 1.206 301.9 0.597 0.039 0.029 29.22 w/device 13:32
#7 2292 Honda base 101401 29.64 77.51 65.97 8/30/9 3.59 0.065 1.209
308.4 0.573 0.04 0.024 28.6 w/device 13:56 #7 2293 Honda base
101408 29.64 77.69 66.45 8/30/9 3.57 0.063 1.315 307.8 0.586 0.04
0.023 28.64 w/device 14:20 #7 2294 Honda base 101442 29.81 75.48
63.08 9/2/97 3.59 0.07 1.771 313.2 0.56 0.036 0.034 28.09 baseline
10:34 2295 Honda base 101451 29.8 75.61 63.36 9/2/98 3.58 0.064
1.641 310.4 0.537 0.035 0.029 28.36 baseline 11.02 2296 Honda base
101460 29.8 75.66 63.68 9/2/97 3.59 0.067 1.605 308.3 0.575 0.036
0.031 28.55 baseline 11:37 2314 Honda base 101502 29.74 79.68 67.19
9/3/97 3.57 0.073 1.586 319.3 0.5 0.042 0.031 27.58 baseline 14:37
2315 Honda base 101510 29.71 80.58 67.37 9/3/97 3.58 0.072 1.869
321.4 0.527 0.043 0.029 27.36 baseline 15:09 2340 Honda base 101772
29.76 76.38 65.23 9/6/97 3.58 0.078 1.805 310.4 0.465 0.043 0.036
28.32 baseline 10:10 2341 Honda base 101780 29.76 76.11 64.98
9/6/97 3.58 0.084 1.855 308.6 0.502 0.045 0.038 28.48 baseline
10:42 2346 Honda base 101860 29.59 79.06 66.02 9/8/97 3.58 0.083
1.862 311.4 0.603 0.046 0.037 28.23 baseline 16:16 2347 Honda base
101869 29.57 79.26 66.19 9/8/97 3.59 0.075 1.882 308.2 0.502 0.045
0.03 28.52 baseline 16:41 2315 Honda base 101510 29.71 80.58 67.37
9/3/97 3.58 0.072 1.869 321.4 0.527 0.043 0.029 27.36 baseline
15:09 2340 Honda base 101772 29.76 76.38 65.23 9/6/97 3.58 0.078
1.805 310.4 0.465 0.043 0.036 28.32 baseline 10:10 2341 Honda base
101780 29.76 76.11 64.98 9/6/97 3.58 0.084 1.855 308.6 0.502 0.045
0.038 28.48 baseline 10:42 2346 Honda base 101860 29.59 79.06 66.02
9/8/97 3.58 0.083 1.862 311.4 0.603 0.046 0.037 28.23 baseline
16:16 2347 Honda base 101869 29.57 79.26 66.19 9/8/97 3.59 0.075
1.882 308.2 0.502 0.045 0.03 28.52 baseline 16:41 2375 Honda base
102081 29.71 74.47 62.77 9/17/9 3.58 0.079 1.812 320.2 0.579 0.043
0.036 27.47 baseline 10:46 2376 Honda base 102089 29.7 75.21 63.2
9/17/9 3.58 0.079 1.998 314.8 0.526 0.044 0.035 27.91 baseline
11:12 2377 Honda base 102098 29.68 75.69 63.67 9/17/9 3.59 0.066
1.234 313.27 0.619 0.042 0.024 28.15 baseline 11:40 2378 Honda base
102107 29.69 76.02 63.59 9/17/9 3.58 0.085 2.483 313.1 0.559 0.046
0.039 27.96 baseline 12:05 2379 Honda base 102119 29.67 76.72 63.93
9/17/9 3.58 0.074 1.894 312.0 0.628 0.044 0.03 28.17 baseline 12:31
2380 Honda base 102128 29.65 77.02 64.67 9/17/9 3.58 0.074 1.858
311.47 0.626 0.044 0.03 28.24 baseline 12:56 2389 Honda additive
102141 29.62 74.32 61.68 9/18/9 3.57 0.067 1.475 318.05 0.591 0.042
0.025 27.7 14:44 2390 Honda additive 102150 29.6 75.35 62.16 9/18/9
3.58 0.069 1.613 312.27 0.618 0.042 0.027 28.19 15:11 2391 Honda
additive 102159 29.59 75.66 62.33 9/18/9 3.57 0.074 1.774 313.7
0.617 0.043 0.03 28.04 15:37 2392 Honda additive 102168 29.58 75.87
62.4 9/18/9 3.58 0.074 1.923 312.12 0.604 0.043 0.031 28.16 16:03
2393 Honda additive 102204 29.68 78.03 64.23 9/19/9 3.58 0.073
1.822 311.64 0.596 0.04 0.034 28.22 10:47 2394 Honda additive
102213 29.68 74.42 62.49 9/19/9 3.58 0.074 1.743 311.53 0.57 0.041
0.033 28.24 11:13 2395 Honda additive 102222 29.67 74.22 62.24
9/19/9 3.58 0.071 1.601 310.82 0.587 0.04 0.03 28.32 11:39 2396
Honda additive 102231 29.67 73.98 62.18 9/19/9 3.57 0.071 1.483
314.80 0.544 0.04 0.031 27.98 13:32 2397 Honda additive 102233
29.65 74.76 62.51 9/19/9 3.58 0.067 1.456 308.84 0.566 0.039 0.028
28.52 14:00 2398 Honda additive 102250 29.64 75.1 62.74 9/19/9 3.58
0.07 1.514 310.41 0.582 0.041 0.029 28.37 14:32 2298 Ford baseline
63973 29.78 76.72 65.55 9/2/97 3.57 0.085 1.413 383.57 0.322 0.025
0.059 23 12:42 2299 Ford baseline 63982 29.77 77.34 65.83 9/2/97
3.58 0.087 1.471 383.56 0.336 0.027 0.06 23 13:22 2300 Ford
baseline 63991 29.76 77.89 66.25 9/2/97 3.57 0.086 1.222 383.71
0.298 0.025 0.061 23.01 14:03 2306 Ford baseline 64035 29.7 80.35
67.28 9/2/97 3.58 0.079 1.099 371.34 0.255 0.025 0.054 23.79
w/device 17:03 2307 Ford baseline 64044 29.71 79.8 66.68 9/2/97
3.57 0.087 1.352 370.60 0.274 0.027 0.06 23.81 w/device 17:35 2308
Ford 6baseline 4053 29.71 79.6 66.34 9/2/97 3.57 0.084 1.379 373.06
0.268 0.027 0.056 23.65 w/device 18:06 2312 Ford baseline 64123
29.77 78.84 66.99 9/3/97 3.57 0.079 1.242 350.59 0.185 0.027 0.052
25.17 w/device 12:47 2313 Ford baseline 64132 29.75 79.75 67.64
9/3/97 3.56 0.078 0.933 352.60 0.173 0.025 0.053 25.06 w/device
13:20 2321 Ford baseline 64394 29.72 76.36 64.27 9/4/97 3.58 0.098
1.496 380.79 0.296 0.029 0.069 23.16 baseline 12:16 2322 Ford
baseline 64403 29.69 76.97 65.15 9/4/97 3.58 0.103 1.564 377.87
0.304 0.03 0.073 23.33 baseline 12:49 2324 Ford baseline 64411
29.68 77.43 65.72 9/4/97 3.58 0.093 1.344 378.96 0.35 0.029 0.064
23.29 baseline 13:25 2333 Ford additive 64446 29.61 79.04 66.64
9/4/97 3.56 0.081 0.993 374.56 0.217 0.025 0.056 23.59 19:02 2334
Ford additive 64454 29.62 78.81 66.32 9/4/97 3.57 0.091 1.225
374.91 0.205 0.028 0.063 23.55 19:35 2336 Ford additive 64463 29.64
78.24 65.74 9/4/97 3.57 0.089 1.228 371.91 0.206 0.028 0.061 23.74
20:15 2337 Ford additive 64472 29.65 78.35 65.9 9/4/97 3.58 0.09
1.243 372.60 0.194 0.027 0.062 23.69 20:44 2338 Ford additive 64481
29.66 78.01 65.63 9/4/97 3.58 0.09 1.266 373.08 0.219 0.029 0.061
23.66 21:15
[0266] Statistical Analysis--When the sample size is small, namely,
less than 20, the standard deviation does not provide a reliable
estimate of the standard deviation of the population. The bias
introduced by the sample size can be removed by correcting the
standard deviation by the statistic known as the Students t. As the
sample size increases, the Students t distribution approaches the
normal distribution. An important application of the Students t
distribution is to use it as the basis for a test to determine if
the difference between two means is significant or due to random
variation. The Students t for two data sets is calculated from the
ratio of the difference in means to the difference in standard
deviations. Where this Students t value falls on the Students t
distribution for that number of samples gives the confidence
probability percent (P-value) that these two samples are the
same.
[0267] Statistical analysis of the results indicated statistically
significant differences in emissions and fuel economy, compared to
baseline runs, for both the additive device and liquid fuel
additive. For the fuel line additive device, a significant decrease
in emissions of CO and NMHC is observed along with an increase in
fuel economy. A substantial NO.sub.x reduction was also observed
for the Ford. Fuel economy was observed to increase with the
decrease in NO.sub.x.
[0268] The two vehicles tested had different fuel supply system
technologies and exhibited different responses (changes in emission
or fuel economy). However, the minimum changes in emissions and
fuel economy observe were as follows: -10.5% in CO; -7.7% in NMHC;
-1% in CO.sub.2, and .+-.1% in fuel economy.
[0269] Similar conclusions were drawn for the liquid fuel additive,
although the magnitude of the effects was smaller and the
uncertainty in the results was greater. Statistical analysis of the
data indicated that all baseline runs come from the same
population. This means that there is no "memory" effect and that
the vehicle returns rapidly to baseline upon removal of the
device.
Vehicle Testing of an OR-2 Additized Diesel Fuel
[0270] A 115 foot tug boat equipped with a General Motors Electro
Motor Division 645-12, 2000 horsepower, 900 rpm two-cycle engine
was operated for approximately 1300 hours on an OR-2 diesel fuel as
described above. At full load, the engine consumed 106 gallons of
fuel per hour. During the 1300 hours of operation on the OR-2
diesel fuel, the fuel consumption averaged 92 gallons of fuel per
hour, corresponding to an improvement in fuel economy of 13.2% or
14 gallons per hour.
[0271] After testing, the head from the #8 cylinder was removed for
inspection. A visual inspection confirmed that the piston crown was
free of ash and carbon deposits, as were the head, injector tip,
and valves (FIGS. 20 and 21). The liner sides were well lubricated
and showed no signs of wear. Port inspection revealed the ring to
be well lubricated with no deposits and no sign of fouling or
sticking.
[0272] A diesel fuel treated with OR-2 as described above was also
tested in a Caterpillar 930 loader. FIG. 22 is a photograph of the
#2 piston top before operation on the additized fuel. FIG. 23 is a
photograph of the #2 piston top after 7385 hours of operation on
the additized fuel. The OR-2 additive provided substantial
protection against deposit formation, as is demonstrated by the
light deposits and areas of bare metal visible on the piston
head.
Emissions Testing of a Phase 3 Compliant California Reformulated
Gasoline
[0273] Additive OR-1 was blended into a base gasoline as described
above to yield a candidate gasoline meeting the CARB Phase 3
specifications as reported in Table 36. The candidate gasoline had
a 90% by volume distillation point of 317.degree. F. (158.3.degree.
C.),.ltoreq.20 ppm sulfur, 1.8.+-.0.2 wt. % oxygen, and.ltoreq.0.80
vol. % benzene. While the ASTM D86 distillation test is commonly
used to measure the distillation points of gasolines, it is
preferred to measure the distillation points according to the
ASTM-3710 standard test method for boiling range distribution of
petroleum fractions by gas chromatography. See 1988 Annual Book of
ASTM Standards, 5:78-88. The ASTM-3710 test has been observed to
yield more accurate and reproducible distillation point data than
the D86 test.
36TABLE 36 Reference and Candidate CaRFG3 Gasolines REFERENCE
CANDIDATE PROPERTY SPEC VALUE TARGET SPEC VALUE TARGET Research
Octane Min 93 92-94 -- -- -- Sensitivity Min 7.5 7.5-9 -- -- --
Lead (organic) max, g/gal 0.050 <0.050 -- -- -- Distillation 10%
.degree. F. 130-140 138 -- -- -- Distillation 50% .degree. F.
210-213 215 .degree. F., Max 220 223 Distillation 90% .degree. F.
300-305 306 .degree. F., Max 317 320 Sulfur Max, ppm 20 20 Max, ppm
20 20 Phosphorus Max, g/gal 0.005 <0.005 -- -- -- RVP psi
6.9-7.0 5.8 psi 7.00 5.8 Olefins Max, vol. % 4 5 Max, vol. % 10 11
Olefins (C3-C5) Max, vol. % 1 <1 Max, vol. % 1 <1 Aromatics
Max, vol. % 25 26 Max, vol. % 34 35 Oxygen wt % 1.8-2.2 0 wt %
1.8+/-0.2 0 Benzene Max, vol. % 0.80 0.80 Max, vol. % 0.80 1.00
[0274] The above description discloses several methods and
materials of the present invention. This invention is susceptible
to modifications in the methods and materials, such as the choice
of base fuel, the components selected for the base formulation, as
well as alterations in the formulation of fuels and additive
mixtures. Such modifications will become apparent to those skilled
in the art from a consideration of this disclosure or practice of
the invention disclosed herein. Consequently, it is not intended
that this invention be limited to the specific embodiments
disclosed herein, but that it cover all modifications and
alternatives coming within the true scope and spirit of the
invention as embodied in the attached claims.
* * * * *