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9.4: Biodiesel Properties and Specifications

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  • 9.4 Biodiesel Properties and Specifications

    To ensure quality biodiesel, there are standards for testing the fuel properly to see that it meets specifications for use. ASTM (an international standards and testing group) has a method to legally define biodiesel for use in diesel engines, labeled ASTM D6751. Table 9.4 shows the test methods necessary for all the expected standards for biodiesel.

    Table 9.4: Legal definition of biodiesel according to ASTM D6751
    Credit: www.biodiesel.org

    Property ASTM Method Limits Units
    Ca & Mg, combined EN 14538 5 max ppm (ug/g)
    Flash point D 93 93 min °C
    Alcohol Control - - -
    1. Methanol content EN14110 0.2 max % mass
    2. Flash point D 93 130 min °C
    Water & Sediment D2709 0.05 max % vol
    Kinematic Viscosity, 40°C D445 1.9-6.0 mm2/sec
    Sulfated Ash D874 0.02 max % mass
    Sulfur - - -
    S 15 Grade D5453 0.0015
    max (15)
    % mass
    (ppm)
    S 500 Grade D5453 0.05 max
    (500)
    % mass
    (ppm)
    Copper Strip Corrosion D130 No. 3 max -
    Cetane D613 47 min -
    Cloud Point D2500 report °C
    Carbon Residue (100% sample) D4530 0.05 max % mass
    Acid Number D664 0.50 max mg KOH/g
    Free Glycerin D6584 0.020 max % mass
    Total Glycerin D6584 0.240 max % mass
    Phosphorus Content D4951 0.001 max % mass
    Distillation, T90 AET D1160 360 max °C
    Sodium/Potassium, combined EN 14538 5 max ppm
    Oxidation Stability EN 14112 3 min Hours
    Cold Soak Filtration Annex to D6751 360 max seconds
    For use in temperatures below -12 °C Annex to D6751 200 max seconds

    There are advantages and disadvantages to using biodiesel compared to ultra-low sulfur diesel. It has a higher lubricity, low sulfur content, and low CO and hydrocarbon emissions. This makes it good to blend with diesel from petroleum to be able to achieve the required specifications for ultra-low sulfur diesel, because ultra-low sulfur diesel has poor lubricity. But as discussed previously, biodiesel has poor cold weather properties. It really depends on the location; for instance, if using biodiesel in the upper Midwest, there could be problems in the winter.

    As with all materials, production and quality of biodiesel is important. Most importantly, the transesterification reaction should reach completion for highest production and quality. Due to the nature of transesterification of triglycerides, a small amount of tri-, di-, and mono-glycerides remain. Figure 9.15 shows the changes in these compounds as the glycerides react to form biodiesel. Some terminology to be aware of: 1) bound glycerol is glycerol that has not been completely separated from the glyceride and is the sum of tri-, di-, and mono-glycerides and 2) total glycerol combines the bound glycerol with the free glycerol.

    yield on y, time on x, Triglycerides fall fast Biodiesel rises rapidly & plateaus @ 90%, di & mono rise briefly @ start then fall 2 0
    Figure 9.15: Conversion of glycerides to biodiesel showing intermediates.

    Credit: BEEMS Module B4

    Glycerol content in biodiesel must be as low as possible, as ASTM standards state. The biodiesel will not technically be “biodiesel” unless ASTM standards are met, which means being below the total glycerol specifications. High glycerol content can cause issues with high viscosity and may contribute to deposit formation and filter plugging. Crude glycerol is often a dark brown color and must be refined and purified before use elsewhere. In biodiesel preparation, brown layers will form, and, possibly, white flakes or sediments, formed from saturated mono-glycerides, that will fall to the bottom of the tank the biodiesel is being stored in.

    Biodiesel is also a great solvent, better than petroleum-based diesel. It can loosen carbon deposits and varnishes that were deposited by petro-diesel and can cause fuel-filter plugging when switching over to biodiesel. Filters should be changed after the first 1,000 miles with biodiesel.

    jar containing layers of light (top, biodiesel) and dark (bottom, glycerol with sediment) colored liquid
    Figure 9.16: Example of biodiesel with crude glycerol and saturated mono-glyceride settled at the bottom.

    Credit: eXtension

    Another issue is cold weather properties for biodiesel. These properties include cloud point, pour point, and cold soak filtration. Biodiesel can form cloud points at a much higher temperature than petro-diesel, close to the freezing point. The cloud point is the temperature that crystals begin to form; it can cause the biodiesel to gel and flow slower than it should. Once the pour point is reached (basically completely frozen), the fuel cannot move. It depends on the normal temperature of the climate as to whether the fuel can be used or blended with petrodiesel. What can complicate it more is the saturated or unsaturated fatty acid content. High saturated fatty acid content can lead to higher fuel stability but higher pour points. High unsaturated acid content can lead to lower pour points but less stability for storing. Figure 9.17 shows a pour point comparison of biodiesels made from various oils (including fatty acid content) compared to petrodiesel. Petro-diesel pour points are significantly lower than biodiesels.

    Pour point comparison. See text description below
    Figure 9.17: Pour point comparison of biodiesels made from various oils (including fatty acid content) and No. 1 diesel fuel.

    Click here for a text alternative to Figure 9.17

    Pour Point Comparison of Biodiesels and the No. 1 diesel fuel. (No. 1 Diesel is neither methyl ester nor ethyl ester)

    Biodiesel Pour Point (Methyl Ester) ºC Pour Point (Ethyl Ester) ºC % Saturated Fatty Acids % Monounsaturated Fatty Acids % Polyunsaturated Fatty Acids
    Canola 15 22 6% 62% 32%
    Safflower 22 22 10% 20% 77%
    Sunflower 24 28 11% 13% 69%
    Soybean 25 30 15% 24% 61%
    asdf -45 - - - -

    Credit: Data from The Biodiesel Handbook

    Cetane number is also an important property for diesel fuels. Cetane number measures the point that the fuel ignites under compression, and this is what we want for a diesel engine. The higher the cetane number, the greater the ease of ignition. Most petro-diesel fuels have a cetane number of 40-50 and meet the ASTM specification for ASTM D975. In general, most biodiesels have higher cetane numbers, 46-60 (some as high as 100) and meet the specifications for ASTM D6751. Because of the higher cetane numbers of biodiesel, the engine running on biodiesel will have an easier time starting and have low idle noise. Table 9.5 shows the heats of combustions for various fuels along with their cetane number.

    Table 9.5: Various biodiesels and No. 2 diesel heats of combustion and cetane number (Credit: National Biodiesel Education Program)
    Fuel Heat of Combustion (Mj/kg) Cetane No.
    Methyl Ester (Soybean) 39.8 46.2
    Ethyl Ester (Soybean) 40.0 48.2
    Butyl Ester (Soybean) 40.7 51.7
    Methyl Ester (Sunflower) 39.8 47.0
    Methyl Ester (Peanut) - 54.0
    Methyl Ester (Rapeseed) 40.1 -
    No. 2 Diesel 45.3 47.0

    If full-strength biodiesel is used (i.e., B100), most engine warranties will not be covered. It will also require replacing rubber seals in older engines. Blends include B2, B10, and B20 (2%, 10%, and 20% biodiesel, respectively). Adding biodiesel as a blend with ultra-low sulfur should improve lubricity for ultra-low sulfur diesel fuel, which will improve engine wear. Emissions of hydrocarbons, CO, NOx, and particulate matter are similar to petrodiesel fuels, although can be reduced in some cases.

    Biodiesel is stored very similarly to petrodiesel. It is stored in clean, dark, and dry environments. It can be stored in aluminum, steel, fluorinated polyethylene, fluorinated polypropylene, and Teflon types of containers. It is best to avoid copper, brass, lead, tin, and zinc containers.

    In another lesson, we will discuss the economics behind using biodiesel.

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