Hemp Biodiesel vs Diesel: Compiled from: Greenfuels and NBB
| Petrol | Hemp | ||
| Can be Procured Domestically:
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| Renewable Resource:
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| Biodegradable:
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| Dangerous to Handle and Store:
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| Could Provide Economic Gain to American
Farmers and Industry:
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| Contributes to Global Warming:
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| Toxic Byproducts of Emission:
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| Contributes to Sulfur Pollution (acid rain):
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| Procurement Pollutes Local Environment:
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| Highly Toxic to Humans and Other Animals:
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• Overall ozone (smog) forming potential of biodiesel is
less than diesel fuel. The ozone forming potential of the speciated hydrocarbon
emissions was nearly 50 percent less than that measured for diesel fuel.1
• Sulfur emissions are essentially eliminated with pure
biodiesel. The exhaust emissions of sulfur oxides and sulfates (major components
of acid rain) from biodiesel were essentially eliminated compared to sulfur
oxides and sulfates from diesel.1
• Criteria pollutants are reduced with biodiesel use.
The use of biodiesel in an unmodified Cummins N14 diesel engine resulted in
substantial reductions of unburned hydrocarbons, carbon monoxide, and
particulate matter. Emissions of nitrogen oxides were slightly increased.1
• Carbon Monoxide: The exhaust emissions of carbon
monoxide (a poisonous gas) from biodiesel were 50 percent lower than carbon
monoxide emissions from diesel.1
• Particulate Matter: Breathing particulate has been
shown to be a human health hazard. The exhaust emissions of particulate matter
from biodiesel were 30 percent lower than overall particulate matter emissions
from diesel.1
• Hydrocarbons: The exhaust emissions of total
hydrocarbons (a contributing factor in the localized formation of smog and
ozone) were 93 percent lower for biodiesel than diesel fuel.1
• Nitrogen Oxides: NOx emissions from biodiesel increase
or decrease depending on the engine family and testing procedures. NOx emissions
(a contributing factor in the localized formation of smog and ozone) from pure
(100%) biodiesel increased in this test by 13 percent. However, biodiesel's lack
of sulfur allows the use of NOx control technologies that cannot be used with
conventional diesel. So, biodiesel NOx emissions can be effectively managed and
efficiently eliminated as a concern of the fuel's use.1
• Biodiesel reduces the health risks associated with
petroleum diesel. Biodiesel emissions showed decreased levels of PAH and
nitrited PAH compounds which have been identified as potential cancer causing
compounds. In the recent testing, PAH compounds were reduced by 75 to 85
percent, with the exception of benzo(a)anthracene, which was reduced by roughly
50 percent. Targeted nPAH compounds were also reduced dramatically with
biodiesel fuel, with 2-nitrofluorene and 1-nitropyrene reduced by 90 percent,
and the rest of the nPAH compounds reduced to only trace levels.1
Environmental & Safety Information:
• Acute Oral Toxicity/Rates: Biodiesel is nontoxic. The
acute oral LD50 (lethal dose) is greater than 17.4 g/Kg body weight. By
comparison, table salt (NaCL) is nearly 10 times more toxic.1
• Skin Irritation: A 24-hr. human patch test indicated
that undiluted biodiesel produced very mild irritation. The irritation was less
than the result produced by a 4 percent soap and water solution.1
• Aquatic Toxicity: A 96-hr. lethal concentration for
bluegill of biodiesel grade methyl esters was greater than 1000 mg/L. Lethal
concentrations at these levels are generally deemed "insignificant" according to
NIOSH (National Institute for Occupational Safety and Health) guidelines in its
Registry of the Toxic Effects of Chemical Substances.1
• Biodegradability: Biodiesel degrades about four times
faster than petroleum diesel. Within 28 days, pure biodiesel degrades 85 to 88
percent in water. Dextrose (a test sugar used as the positive control when
testing biodegradability) degraded at the same rate. Blending biodiesel with
diesel fuel accelerates its biodegradability. For example, blends of 20 percent
biodiesel and 80 percent diesel fuel degrade twice as fast as #2 diesel alone.1
• Flash Point: The flash point of a fuel is defined as
the temperature at which it will ignite when exposed to a spark or flame.
Biodiesel's flash point is over 300 deg. Fahrenheit, well above petroleum based
diesel fuel's flash point of around 125 deg. Fahrenheit. Testing has shown the
flash point of biodiesel blends increases as the percentage of biodiesel
increases. Therefore, biodiesel and blends of biodiesel with petroleum diesel
are safer to store, handle, and use than conventional diesel fuel.1
Ethanol:
Although the concept of ethanol as a fuel began as early as the
first Model T car designed by Henry Ford, American usage of ethanol-blended
gasoline did not begin until the late 1970s. Environmentally, the use of ethanol
blends has since assisted in reducing carbon monoxide emissions as mandated by
the U.S. Clean Air Act of 1990.2
Hemp Ethanol vs Petrol:
Net Reduction in Ground-level Ozone Forming Emissions:
Ground-level ozone causes human respiratory problems and damages many plants but
does nothing to increase ozone concentration in the stratosphere that protects
the earth from the sun's ultraviolet radiation. There are many compounds that
react with sunlight to form ground-level ozone, which, in combination with
moisture and particulate matter, creates 'smog', the most visible form of air
pollution. These compounds include carbon monoxide, unburned hydrocarbons,
benzene, and nitrogen oxides (nitrous oxide and nitric oxide).2
In an effort to reduce automobile emissions that contribute to
the formation of ground-level ozone, the highly populated state of California
has legislated stringent automobile emissions standards. Several Canadian urban
centers record similar hazardous exposures to carbon monoxide, especially during
late fall and winter, and would be out of compliance if Canada implemented air
quality legislation equivalent to the U.S. Clean Air Act. In Canada, southern
Ontario, southern British Columbia, and parts of Nova Scotia and New Brunswick
are prone to smog. Using oxygenated fuels, such as ethanol, is one way of
addressing the issue of air pollution.2
The net effect of ethanol use results in an overall decrease in
ozone formation. The emissions produced by burning ethanol are less reactive
with sunlight than those produced by burning gasoline, resulting in a lower
potential for forming the damaging ozone. In Canada, where the volatility of
ethanol blends must match normal gasoline, the ozone forming potential of
ethanol blends is even lower than in the U.S., where ethanol blends are allowed
to have increased volatility.2
Reduction in Harmful Greenhouse Gases: The 'Greenhouse
Effect' refers to the Earth's atmosphere trapping the sun's radiation. It is a
term often used synonymously with 'Global Warming', which refers to the
increasing average global temperature, arising from an increase in greenhouse
gases from industrial activity and population growth. Greenhouse gases
contributing to the Greenhouse Effect include carbon dioxide, methane, and
nitrogen oxide.2
The term 'Climate Change' refers to a wide range of changes in
weather patterns that result from global warming. A substantial increase in the
Earth's average temperature could result in a change in agricultural patterns
and melting of polar ice caps, raising sea levels and causing flooding of
low-lying coastal areas.2
The use of ethanol-blended fuels such as E85 (85% ethanol and
15% gasoline) can reduce the net emissions of greenhouse gases by as much as
37.1%. Ethanol-blended fuel as E10 (10% ethanol and 90% gasoline) reduces
greenhouse gases by up to 3.9%. By the year 2010, the reductions for E85 and E10
are projected to be 44.5% and 4.6%, respectively. This represents only a small
percentage of the total greenhouse gas reduction required from the Kyoto
Protocol. It is expected that once ethanol is made from cellulose, the
greenhouse gas emissions reductions will further improve. Hemp produces four
times as much cellulose per acre than trees.2
Emissions Reductions from Using Ethanol-Blended Fuels:
Reduction in Net Carbon Dioxide (CO2) Emissions: Use of
10% ethanol-blended fuels results in a 6-10% net reduction of CO2. The carbon
dioxide released from ethanol production and use is less than that absorbed by
the plants and soil organic matter used to produce ethanol. The carbon dioxide
produced during ethanol production and gasoline combustion is extracted from the
atmosphere by plants for starch and sugar formation during photosynthesis. It is
assimilated by the crop in its roots, stalks and leaves, which usually return to
the soil to maintain organic matter, or in the grain, the portion currently used
to produce ethanol. Over time, the organic matter breaks down to CO2, but with
the implementation of conservation measures, such as reduced tillage, the soil
organic matter will build up. Therefore, by increasing its organic matter
content, the soil acts as a significant sink for carbon dioxide.2
Volatile Organic Compounds (VOC's):Volatile organic
compounds are highly reactive in the atmosphere, and are significant sources of
ground-level ozone formation. Because ethanol oxygenates the fuel, there is
approximately a 7% overall decrease in exhaust VOC's emitted from low-level
ethanol-blended fuels relative to conventional fossil fuels. In high level
blends, the potential for exhaust VOC reduction is 30% or more. 2
Sulphur Dioxide (SO2) and Particulates: As ethanol
contains no sulphur, and because it promotes more complete fuel combustion,
blending gasoline with ethanol would reduce any potential for these emissions
and the adverse effects of sulphur. In diesel engines, where SO2 and
particulates are of concern, the use of ethanol-blended diesel or neat ethanol
shows a significant reduction in these emissions. 2
Hemp Biodiesel vs Diesel: Compiled from: Greenfuels
and NBB
• Overall ozone (smog) forming potential of biodiesel is
less than diesel fuel. The ozone forming potential of the speciated hydrocarbon
emissions was nearly 50 percent less than that measured for diesel fuel.1
• Sulfur emissions are essentially eliminated with pure
biodiesel. The exhaust emissions of sulfur oxides and sulfates (major components
of acid rain) from biodiesel were essentially eliminated compared to sulfur
oxides and sulfates from diesel.1
• Criteria pollutants are reduced with biodiesel use.
The use of biodiesel in an unmodified Cummins N14 diesel engine resulted in
substantial reductions of unburned hydrocarbons, carbon monoxide, and
particulate matter. Emissions of nitrogen oxides were slightly increased.1
• Carbon Monoxide: The exhaust emissions of carbon
monoxide (a poisonous gas) from biodiesel were 50 percent lower than carbon
monoxide emissions from diesel.1
• Particulate Matter: Breathing particulate has been
shown to be a human health hazard. The exhaust emissions of particulate matter
from biodiesel were 30 percent lower than overall particulate matter emissions
from diesel.1
• Hydrocarbons: The exhaust emissions of total
hydrocarbons (a contributing factor in the localized formation of smog and
ozone) were 93 percent lower for biodiesel than diesel fuel.1
• Nitrogen Oxides: NOx emissions from biodiesel increase
or decrease depending on the engine family and testing procedures. NOx emissions
(a contributing factor in the localized formation of smog and ozone) from pure
(100%) biodiesel increased in this test by 13 percent. However, biodiesel's lack
of sulfur allows the use of NOx control technologies that cannot be used with
conventional diesel. So, biodiesel NOx emissions can be effectively managed and
efficiently eliminated as a concern of the fuel's use.1
• Biodiesel reduces the health risks associated with
petroleum diesel. Biodiesel emissions showed decreased levels of PAH and
nitrited PAH compounds which have been identified as potential cancer causing
compounds. In the recent testing, PAH compounds were reduced by 75 to 85
percent, with the exception of benzo(a)anthracene, which was reduced by roughly
50 percent. Targeted nPAH compounds were also reduced dramatically with
biodiesel fuel, with 2-nitrofluorene and 1-nitropyrene reduced by 90 percent,
and the rest of the nPAH compounds reduced to only trace levels.1
Environmental & Safety Information:
• Acute Oral Toxicity/Rates: Biodiesel is nontoxic. The
acute oral LD50 (lethal dose) is greater than 17.4 g/Kg body weight. By
comparison, table salt (NaCL) is nearly 10 times more toxic.1
• Skin Irritation: A 24-hr. human patch test indicated
that undiluted biodiesel produced very mild irritation. The irritation was less
than the result produced by a 4 percent soap and water solution.1
• Aquatic Toxicity: A 96-hr. lethal concentration for
bluegill of biodiesel grade methyl esters was greater than 1000 mg/L. Lethal
concentrations at these levels are generally deemed "insignificant" according to
NIOSH (National Institute for Occupational Safety and Health) guidelines in its
Registry of the Toxic Effects of Chemical Substances.1
• Biodegradability: Biodiesel degrades about four times
faster than petroleum diesel. Within 28 days, pure biodiesel degrades 85 to 88
percent in water. Dextrose (a test sugar used as the positive control when
testing biodegradability) degraded at the same rate. Blending biodiesel with
diesel fuel accelerates its biodegradability. For example, blends of 20 percent
biodiesel and 80 percent diesel fuel degrade twice as fast as #2 diesel alone.1
• Flash Point: The flash point of a fuel is defined as
the temperature at which it will ignite when exposed to a spark or flame.
Biodiesel's flash point is over 300 deg. Fahrenheit, well above petroleum based
diesel fuel's flash point of around 125 deg. Fahrenheit. Testing has shown the
flash point of biodiesel blends increases as the percentage of biodiesel
increases. Therefore, biodiesel and blends of biodiesel with petroleum diesel
are safer to store, handle, and use than conventional diesel fuel.1
Ethanol:
Although the concept of ethanol as a fuel began as early as the
first Model T car designed by Henry Ford, American usage of ethanol-blended
gasoline did not begin until the late 1970s. Environmentally, the use of ethanol
blends has since assisted in reducing carbon monoxide emissions as mandated by
the U.S. Clean Air Act of 1990.2
Hemp Ethanol vs Petrol:
Net Reduction in Ground-level Ozone Forming Emissions:
Ground-level ozone causes human respiratory problems and damages many plants but
does nothing to increase ozone concentration in the stratosphere that protects
the earth from the sun's ultraviolet radiation. There are many compounds that
react with sunlight to form ground-level ozone, which, in combination with
moisture and particulate matter, creates 'smog', the most visible form of air
pollution. These compounds include carbon monoxide, unburned hydrocarbons,
benzene, and nitrogen oxides (nitrous oxide and nitric oxide).2
In an effort to reduce automobile emissions that contribute to
the formation of ground-level ozone, the highly populated state of California
has legislated stringent automobile emissions standards. Several Canadian urban
centers record similar hazardous exposures to carbon monoxide, especially during
late fall and winter, and would be out of compliance if Canada implemented air
quality legislation equivalent to the U.S. Clean Air Act. In Canada, southern
Ontario, southern British Columbia, and parts of Nova Scotia and New Brunswick
are prone to smog. Using oxygenated fuels, such as ethanol, is one way of
addressing the issue of air pollution.2
The net effect of ethanol use results in an overall decrease in
ozone formation. The emissions produced by burning ethanol are less reactive
with sunlight than those produced by burning gasoline, resulting in a lower
potential for forming the damaging ozone. In Canada, where the volatility of
ethanol blends must match normal gasoline, the ozone forming potential of
ethanol blends is even lower than in the U.S., where ethanol blends are allowed
to have increased volatility.2
Reduction in Harmful Greenhouse Gases: The 'Greenhouse
Effect' refers to the Earth's atmosphere trapping the sun's radiation. It is a
term often used synonymously with 'Global Warming', which refers to the
increasing average global temperature, arising from an increase in greenhouse
gases from industrial activity and population growth. Greenhouse gases
contributing to the Greenhouse Effect include carbon dioxide, methane, and
nitrogen oxide.2
The term 'Climate Change' refers to a wide range of changes in
weather patterns that result from global warming. A substantial increase in the
Earth's average temperature could result in a change in agricultural patterns
and melting of polar ice caps, raising sea levels and causing flooding of
low-lying coastal areas.2
The use of ethanol-blended fuels such as E85 (85% ethanol and
15% gasoline) can reduce the net emissions of greenhouse gases by as much as
37.1%. Ethanol-blended fuel as E10 (10% ethanol and 90% gasoline) reduces
greenhouse gases by up to 3.9%. By the year 2010, the reductions for E85 and E10
are projected to be 44.5% and 4.6%, respectively. This represents only a small
percentage of the total greenhouse gas reduction required from the Kyoto
Protocol. It is expected that once ethanol is made from cellulose, the
greenhouse gas emissions reductions will further improve. Hemp produces four
times as much cellulose per acre than trees.2
Emissions Reductions from Using Ethanol-Blended Fuels:
Reduction in Net Carbon Dioxide (CO2) Emissions: Use of
10% ethanol-blended fuels results in a 6-10% net reduction of CO2. The carbon
dioxide released from ethanol production and use is less than that absorbed by
the plants and soil organic matter used to produce ethanol. The carbon dioxide
produced during ethanol production and gasoline combustion is extracted from the
atmosphere by plants for starch and sugar formation during photosynthesis. It is
assimilated by the crop in its roots, stalks and leaves, which usually return to
the soil to maintain organic matter, or in the grain, the portion currently used
to produce ethanol. Over time, the organic matter breaks down to CO2, but with
the implementation of conservation measures, such as reduced tillage, the soil
organic matter will build up. Therefore, by increasing its organic matter
content, the soil acts as a significant sink for carbon dioxide.2
Volatile Organic Compounds (VOC's):Volatile organic
compounds are highly reactive in the atmosphere, and are significant sources of
ground-level ozone formation. Because ethanol oxygenates the fuel, there is
approximately a 7% overall decrease in exhaust VOC's emitted from low-level
ethanol-blended fuels relative to conventional fossil fuels. In high level
blends, the potential for exhaust VOC reduction is 30% or more. 2
Sulphur Dioxide (SO2) and Particulates: As ethanol
contains no sulphur, and because it promotes more complete fuel combustion,
blending gasoline with ethanol would reduce any potential for these emissions
and the adverse effects of sulphur. In diesel engines, where SO2 and
particulates are of concern, the use of ethanol-blended diesel or neat ethanol
shows a significant reduction in these emissions. 2
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