
SEBU8455
51
Maintenance Section
Re
fi
ll Capacities
“EN590 - Grades A to F and class 0 to 4”
“ASTM D975 Grade No. 1-D and 2-D”
“JIS K2204 Grades 1, 2 & 3 & Special Grade 3”
acceptable provided lubricity ware scar diameter
does not exceed of 0.46 mm (0.01811 inch) as per
“ISO 12156-1”.
“BS2869 - Class A2 Off Highway Gas Oil, Red Diesel”
Note:
The lubricity of these fuels must not exceed
wear scar diameter of 0.46 mm (0.01811 inch) as per
“ISO 12156-1”. Refer to “Lubricity”.
Group 2: Aviation Kerosene Fuels
Following kerosene and jet fuel speci
fi
cations are
acceptable alternative fuels and may be used on a
contingency bases, for emergency or continuous
use, where standard diesel fuel is not available and
where legislation allows their use:
“MIL-DTL-83133 NATO F34 (JP-8)”
“MIL-DTL-83133 NATO F35”
“MIL-DTL-5624 NATO F44 (JP-5)”
“MIL-DTL-38219 (USAF) (JP7)”
“NATO XF63”
“ASTM D1655 JET A”
“ASTM D1655 JET A1”
NOTICE
These fuels are only acceptable when used with ap-
propriate lubricity additive and must meet minimum
requirements that are listed in table 7. The lubricity
of these fuels must not exceed wear scar diameter of
0.46 mm (0.01811 inch) as per “ISO 12156-1”. Refer
to “Lubricity”.
Note:
Minimum cetane number of 40 is recommended
otherwise cold starting problems or light load mis
fi
re
might occur. Since jet fuel speci
fi
cations do not
mention cetane requirements, Perkins recommends
that a fuel sample is taken to determine the cetane
number.
Note:
Fuels must have minimum viscosity of 1.4
cSt delivered to the fuel injection pump. Cooling
of the fuel may be required to maintain 1.4 cSt or
greater viscosity at the fuel injection pump. Perkins
recommends that the actual viscosity of the fuel be
measured in order to determine if a fuel cooler is
needed. Refer to “Viscosity”.
Note:
Rated power loss of up to 10 percent is
possible due to lower density and lower viscosity of
jet fuels compared to diesel fuels.
Biodiesel Fuel
Biodiesel is a fuel that can be de
fi
ned as mono-alkyl
esters of fatty acids. Biodiesel is a fuel that can be
made from various feedstock. The most commonly
available biodiesel in Europe is Rape Methyl Ester
(REM). This biodiesel is derived from rapeseed
oil. Soy Methyl Ester (SME) is the most common
biodiesel in the United States. This biodiesel is
derived from soybean oil. Soybean oil or rapeseed oil
are the primary feedstocks. These fuels are together
known as Fatty Acid Methyl Esters (FAME).
Raw pressed vegetable oils are NOT acceptable for
use as a fuel in any concentration in compression
engines. Without esteri
fi
cation, oil will gel in the
crankcase and the fuel tank. These fuels may not be
compatible with many of the elastomers that are used
in engines that are manufactured today. In original
forms, these oils are not suitable for use as a fuel
in compression engines. Alternate base stocks for
biodiesel may include animal tallow, waste cooking
oils, or various other feedstocks. In order to use any
of the products that are listed as fuel, the oil must
be esteri
fi
ed.
Fuel made of 100 percent FAME is generally referred
to as B100 biodiesel or neat biodiesel.
Biodiesel can be blended with distillate diesel fuel.
The blends can be used as fuel. The most commonly
available biodiesel blends are B5, which is 5 percent
biodiesel and 95 percent distillate diesel fuel. B20,
which is 20 percent biodiesel and 80 percent distillate
diesel fuel.
Note:
The percentages given are volume-based.
The U.S. distillate diesel fuel speci
fi
cation “ASTM
D975-09a” includes up to B5 (5 percent) biodiesel.
European distillate diesel fuel speci
fi
cation
“EN590:2010” includes up B7 (7 percent) biodiesel.
Note:
Engines that are manufactured by Perkins
are certi
fi
ed by use of the prescribed Environmental
Protection Agency (EPA) and European Certi
fi
cation
fuels. Perkins does not certify engines on any other
fuel. The user of the engine has the responsibility
of using the correct fuel that is recommended by
the manufacturer and allowed by the EPA and other
appropriate regulatory agencies.