BIODIESEL
BIODIESEL -Using renewable resources2007 Science Outreach
WorkshopIntroduction: One of the ways in which processes can be
made greener is to use renewable resources to replace nonrenewable
starting materials. Chemical processes that rely on materials that
cannot be supplied in a sustainable fashion are fundamentally
harmful to the environment. Such processes can eventually deplete a
resource. While it makes little sense to become dependent on any
resource that exists in finite quantities, many processes are in
this very position because although they are finite, they are also
vast. Petroleum is a good example. Because it is presently so
plentiful, too little regard has been given to finding a renewable
alternative. Yet our petroleum reserves are sure to run out,
possibly in a matter of decades. The conversion of plant material
into usable fuel is one approach that could be part of a larger
alternative to the use of petroleum. In this experiment, we explore
the making of fuel from vegetable oil as a demonstration of the
green chemistry principle of using renewable resources, such as
substances derived from growing plants, rather than irreplaceable
materials like the earths petroleum and natural gas
supplies.Reference: This experiment, taken from the American
Chemical Societys Introduction to Green Chemistry, is adapted from
The Royal Society of Chemistry, Learning about Materials; The Royal
Society of Chemistry: London, 1998.
Background information:
Diesel is a common fuel used to power many large trucks (like
the 18-wheel rigs commonly found on interstate highways) and heavy
equipment (such as tractors and backhoes). Diesel fuel is made from
crude oil that was formed over millions of years by the
decomposition of prehistoric plants and animals. Through the use of
an oil well, crude oil is pumped out of the ground and transferred
(often by large ocean tankers) to oil distillation units. Crude oil
contains widely varying organic chemicals that range in size from
small molecules with only 1 carbon atom to very large molecules
with more than 20 carbon atoms that can be separated into various
fractions (or components) based on the size with a distillation
tower.
Chemists have created a substitute for diesel by chemically
changing various fats and oils. By using a chemical technique
called transesterification, chemists can turn oils from various
crops (most commonly canola and soy) into a viable diesel
substitute. One of the major advantages of using biodiesel instead
of diesel is that biodiesel is derived from a renewable resource.
As mentioned before, diesel comes from crude oil, which takes
millions of years to form. During the next few million years, more
underground pools of crude oil will be formed; however, it is
consumed at a rate that is drastically faster than that at which it
is forming. Most experts believe that at current production, crude
oil will be economically exhausted in the next 40 years
(www.wri.org/wri/climate/jm_oil_003.html). Conversely, biodiesel is
made from renewable resources, namely, oils derived from farm
crops, such as soybeans.
Biodiesel also creates lower sulfur emissions when it is burned,
which helps reduce acid rain. It also breaks down more quickly in
the environment, thus lessening the severity of an accidental spill
compared with crude oil. Finally, unlike fossil fuels such as
gasoline, biodiesel does not cause an overall increase in the
amount of CO2 (a greenhouse gas) in the atmosphere when the fuel is
burned. Soybeans and other plants that produce oils for making
biodiesel take up CO2 from the atmosphere as they grow. When oil is
extracted from the mature plants and burned, and the remainder of
the plant material decomposes, CO2 is returned to the atmosphere.
Thus there is a balance between the amount of CO2 removed from the
atmosphere by growing plants and returned to the atmosphere by the
same plants. No excess CO2 is produced to contribute to global
climate change (www.ott.doe.gov/biofuels/environment.html).
Part 1. Making biodiesel
Biodiesel is a mixture of methyl esters of fatty acids. It can
be made very easily from vegetable cooking oil. Enough fuel can be
produced from this lab to burn in a later activity, although it is
not pure enough to actually be used as fuel in a car or truck. The
synthesis is a simple chemical reaction that produces biodiesel and
glycerol. Cooking oil is mixed with methanol, while potassium
hydroxide is added as a catalyst. The products separate into two
layers, with the biodiesel on the top. The biodiesel is separated
and washed and is then ready for further experimentation.
Biodiesel consists of three principal feed stocks:
1. Oil: Glycerides are commonly known as oils or fats,
chemically speaking these are long chain fatty acids joined by a
glycerin backbone.
2. Alcohol: Methanol is one of the most common industrial
alcohols; because of its
abundant supply its most often the least expensive alcohol as
well.
3. Catalyst: the third reactant needed is a catalyst that
initiates the reaction and allows the
oils to break. The strong base solutions typically used are
sodium hydroxide (NaOH) and
potassium hydroxide (KOH). This experiment will be using KOH as
catalyst.
Procedure:
Safety: You must wear goggles and an apron. Methanol is
flammable and poisonous. Sodium hydroxide is corrosive.
1. Record your starting observations (color, viscosity, odor) in
a data table and any changes that take
place. (Data to include observations before, during and after
the reaction.)
2. Measure 3 mL of methanol into a large test tube.
3. Using a graduated pipette, carefully add 0.5 mL of 9M KOH to
the alcohol. (Sodium hydroxide is
corrosive) Swirl gently.
4. Use a graduated cylinder to measure 12 mL of warm cooking oil
into your test tube.
5. Swirl and shake the mixture for 10 minutes. Occasionally
release any pressure.
6. Wash the product using 1 mL of salt water. Invert gently a
few times and let stand.
7. Allow the mixture to sit and separate. A few drips of salt
water to help the separation process. 8. Carefully remove the top
layer (biodiesel) using a pipette and put into a clean test
tube.
9. Add a small scoop of anhydrous sodium sulfate and swirl
gently. Stopper and store in your drawer
for the next lab day.
Observations (part 1):
Starting ObservationsInterim ObservationsFinal Observation
Color
Viscosity
Other
Part 2. Testing biodieselHow does biodiesel compare with other
fuels? Just because we can produce a fuel from an alternative
source, does that mean it is a good idea? There are many factors
that go into the decision to use alternative fuels. Ideally, the
physical characteristics of an alternative fuel meet or exceed
those of the traditional product
Procedure:
Safety: This procedure involves the burning of liquid fuel. Know
the location of fire extinguisher and how to smother a small fire
with a wet paper towel.
1. Measure the amount of biodiesel you have collected and
compare it to the amount of vegetable oil you started with. Also
record the characteristics of your biodiesel (color, viscosity,
odor) and compare them to those of the original oil.
2. Pour 125 mL of tap water into the filter flask and add 20
drops of universal indicator. The solution should be violet or at
the most basic end of the universal indicator color range.
3. Pour 10 mL of solution prepared in step 1
into a small beaker labeled control. Set this
control aside for later comparisons.
4. Assemble the apparatus illustrated in the
figure at right.
5. Then turn on the water tap so the aspirator
pulls air through the flask. Mark or note the position of the
faucet handle so you can run the
aspirator at the same flow rate later in the experiment. You
should see gas bubbles coming from
the tube into the universal indicator.
6. Without anything burning, allow the setup to run until the
solution turns yellow or for two minutes
(whichever occurs first). Record the time and what happens in
the funnel(point A), the tube(point B),
and the universal indicator. Record the results in the data
table below.
7. Refresh the universal indicator solution and repeat the
experiment with a burner filled with traditional
diesel fuel. Placed a fluffed piece of steel wool into a dry
evaporating dish. Add 40 drips of fuel on to
the surface of the steel wool.8. Turn on the water and ignite
the fuel away from the funnel. Position the lit burner directly
under the
funnel so as to capture the fumes from the burning fuel. Start
your timing and allow the apparatus to
run until the universal indicator turns yellow.
9. Record the time required for a color change and the amount of
soot in the funnel (point A), the
amount of water vapor in the glass tube (point B).10. Refresh
the apparatus with clean water and indicator, use a dry paper towel
to wipe any soot
from the funnel and repeat the experiment using a burner filled
with biodiesel. Light the burner and
adjust the flame to match the height of the previous trial
before placing it under the funnel.
11. Record the time and what happens in the funnel (point A),
the tube (point B), and the universal
indicator.
12. Dismantle and clean the funnel with a dry paper towel.
Dispose of the steel wool and wipe up.
Observations: Part 2
Trial TestedTime of color changes (minutes)Observations of
Universal IndicatorObservations at Point A (funnel)Observations at
Point B (glass tube)
No Fuel
Trad.
Diesel
Biodiesel
Questions:
1. What changes did you see between the characteristics of the
starting materials (cooking oil,
methanol, and potassium hydroxide solution) and the final
products (biodiesel and glycerol)? What
evidence is there that a chemical reaction has occurred? [4]
2. In the commercial production of biodiesel, 1200 kg of
vegetable oil produces 1100 kg of crude
biodiesel. Calculate the percent yield of the commercial process
and for your process in the lab.
How does your yield compare? Suggest reasons for any
differences. [3]
3. What is the purpose of washing the biodiesel mixture with
salt water? [1]
4. After burning both fuels, compare the time it took to change
the color of the universal indicator in each test. Explain reasons
for any differences you observed. [3]
5. What was the purpose of the No Fuel test? What did it show?
[2]
6. Compare the amount of soot collected in the funnel (point A)
and in the water vapor in the tube (point B) in each of the
experimental runs. [3]
7. Is biodiesel really green? Explain at least two arguments in
support of the idea that biodiesel is a greener fuel. Also present
one argument that biodiesel is not a greener fuel. Reference your
lab data when appropriate. [4]
Sources:
www.afdc.doe.gov/altfuel/biodiesel.html
www.newton.dep.anl.gov/natbltn/500-599/nb543.htm
www.afdc.doe.gov/questions.html
Optional Activity
Part 3. Measuring the Heat of Combustion of Biodiesel
How does biodiesel compare with other fuels? Just because we can
produce a fuel from an alternative source, does that mean it is a
good idea? There are many factors that go into the decision to use
alternative fuels. Ideally, the physical characteristics of an
alternative fuel meet or exceed those of the traditional product.
But how are fuels evaluated in the first place? In this lab
activity biodiesels heat of combustion is determined.
Procedure:
Safety: This procedure involves the burning of liquid fuel. Know
the location of fire extinguisher and how to smother a small fire
with a wet paper towel.
1. Use a disposable pipette and rubber bulb to transfer ~2 mL of
your biodiesel product to a porcelain
crucible. Add a piece of candle wicking approximately 1 long.
One end of wick should be in the
biodiesel and the other above the surface. Re-weigh the crucible
and record the total mass.
2. Place 75.0 mL cold water in an empty soda can. Assemble
the apparatus shown by hanging the soda can from a stirring
rod supported by an iron ring. Place a thermometer in the
can
and allow it to sit for 5 minutes. Replace the sample holder
in
the image to the left with your crucible of biodiesel.
Adjust
the height of the can so that it hangs just over the
crucible.
3. Record the starting temperature of the water in the can.
Light the wick and let it burn for 5 minutes before gently
blowing out the flame. Remember that the crucible will be
hot! Record the final temperature of the water.
4. After the crucible has cooled, obtain its final mass. Pour
all
remaining biodiesel into the waste bottle in the hood. Empty
your can down the drain and clean up your lab bench.
5. For this part of the lab you must determine the heat of
combustion of biodiesel in kJ/g. Determine the mass of
biodiesel that burned. Assume that all heat release by the
combustion was absorbed by the water in the can. Use the
following equation to determine the heat of combustion for
your biodiesel.
E = s x m x T
where s = 4.184 J/g oC
m = mass of water in can
T = Tfinal - Tinitial Mass of Empty Crucible (g)Starting Temp of
Water (C)
Mass of Crucible + FuelFinal Temp of Water (C)
Final Mass of Crucible Change in Temp of Water (C)
Mass of Fuel BurnedStarting Temp of Water (C)
Data Table:
Questions:
1. Compare the heat of combustion of biodiesel to that of octane
(48.23 kJ/g).
2. Describe any sources of error that could affect this
experiment. Indicate if each error would raise
or lower the final value for the experimental value for the heat
of combustion.
Instructional notes
Instructional notes on activity 1: Making biodiesel
In this activity, students make biodiesel from cooking oil. The
cooking oil is mixed with methanol and a catalyst (potassium
hydroxide). Cooking oil is a lipid called a triglyceride or
triacyglycerol. The structure of this type of lipid is
characteristic of all animal and plant fats. It consists of a
glycerol attached to three fatty acids. Differences among the fats
are due to the different fatty acids connected to the glycerol. In
making biodiesel, the reaction breaks the bond between the glycerol
and the fatty acids. A methyl group is added to the end of the
fatty acid, which is what we call biodiesel, and the other products
are glycerol and the remaining sodium hydroxide catalyst. If any
water is present, the reaction will yield soap, not biodiesel. Tell
students to use dry glassware, and keep reagent bottles capped. It
takes awhile to get the NaOH to dissolve in methanol. Cooling with
an ice bath will speed dissolution.
Instructional notes on activity 2: Testing biodiesel
This activity is designed to test the characteristics of the
biodiesel prepared by students with a semiquantitative measure. The
idea is that the waste products that are given off by the
combustion of the biodiesel include CO2 and soot. A rough measure
of the amount of CO2 is gained by bubbling the waste gas through a
universal indicator. Because CO2 forms an acid when it dissolves in
water (carbonic acid), the rate of change in color of the universal
indicator is proportional to the amount of CO2 in the combustion
products. Students are also asked to compare the amount of soot
that collects. Soot is uncombusted carbon and represents incomplete
combustion of the fuel. Less efficient fuel generally produces more
soot.
Answers to questions:
1. What changes did you see between the characteristics of the
starting materials (cooking oil, methanol, and potassium hydroxide
solution) and the final products (biodiesel and glycerol)? Cooking
oil is nonpolar, greasy, and slippery. Methanol is a colorless
liquid that may have an odor and evaporates quickly. The potassium
hydroxide solution is colorless and odorless, and it may be
slippery when touched (not recommended, because it is very
caustic). Glycerol is a slightly viscous liquid that is colorless
and odorless. The biodiesel appearance will vary but may have some
slight color and odor. What signs did you observe that a chemical
reaction had taken place? The mixture separates into two layers,
the biodiesel and the glycerol.
2. In the commercial production of biodiesel, 1200 kg of
vegetable oil produces 1100 kg of crude biodiesel. How does your
yield compare to this? Student answers will vary. In the example
given, it is approximately a 90% yield.
3. What is the purpose of the washing with distilled water? The
washing removes the potassium hydroxide catalyst.
4. Compare the time it took to change the color of the universal
indicator in each test. Explain any differences you observed. Gas
mixtures with a high concentration of CO2 will cause a faster color
change in the universal indicator. The amount of CO2 and SO2
released from combustion is an indication of the efficiency of the
combustion reaction. If biodiesel is a fair substitute for
petrodiesel, you would expect it to perform similarly. Traditional
diesel does contain sulfur and should produce a somewhat faster
color change.
5. What was the purpose of the No fuel test? What did it show?
This trial acts as a control and provides a baseline for
comparison. Air should not change the color of the indicator very
much which shows that combustion products do pollute the water.
6. Compare the amount of soot collected in the funnel and in the
tube (point B) in each of
the experimental runs. Soot occurs when a combustion reaction is
not complete. The more soot, the less efficient the combustion
process. Again, we would expect the biodiesel and petrodiesel to be
similar.
7. Is biodiesel really green? Explain at least one argument in
support of the idea that biodiesel is a greener fuel. Also present
one argument that biodiesel is not a greener fuel.
One green feature of biodiesel is that it does use renewable
resources. It is also lower in sulfur content and produces fewer
particulates. It is much less toxic than fossil diesel and is more
biodegradable. Some not so green features are that it is still a
combustion reaction that releases the same types of exhaust
emissions (nitrogen oxides, carbon monoxide, hydrocarbons, soot,
etc.) as those released into the atmosphere by diesel fuel;
however, biodiesel releases lower quantities of these. A slightly
lower energy content of biodiesel may result in having to use more
to get equivalent results. Approximately 1.1 gallons of biodiesel
give the energy equivalent to 1.0 gallons of diesel fuel.
References:
1. The Office of Fuels Development for the U.S. Department of
Energy at www.ott.doe.gov/biofuels.
2. The National Biodiesel Board, www.biodiesel.org.
3. A comprehensive report on the economics and science of using
soybeans to make biodiesel is presented
at www.mda.state.mn.us/ams/soydieselreport.pdf.
2007 Eric Knispel
