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UnderstandingFuel Oils
UnderstandingFuel Oils
TopicsTopics IntroductionIntroduction Refining ProcessesRefining Processes Fuel oil compositionFuel oil composition Fuel Oil productionFuel Oil production A Modern refineryA Modern refinery Refining trends with exampleRefining trends with example ConclusionsConclusions Key quality indicatorsKey quality indicators Quality trends Vs Technology Quality trends Vs Technology Effect of Fuel oil quality on engine Effect of Fuel oil quality on engine
performanceperformance Storage & handling-A Recall Storage & handling-A Recall
IntroductionIntroduction
Fuel oil is Cheap but has fair CVFuel oil is Cheap but has fair CV Residual FuelResidual Fuel Diesel CycleDiesel Cycle Low Cetane valueLow Cetane value Hence for Low/Medium speedHence for Low/Medium speed Natural sourceNatural source Not much can be done on qualityNot much can be done on quality Engines built to suit this fuelEngines built to suit this fuel
Viscosity,20°C
% asphaltenes
Gasoline (C5-80°)
Heavy gasoline (80-160°)
Kerosene (160-250°)
Middle distillate (250-300°)
Heavy distillate (300-400°)
Residue (400 +)
35.8
5.8
4.09
9.05
12.58
14.12
7.51
50.42
10.2
0.93
5.56
12.02
15.5
17.19
8.72
38.71
ARABIANHEAVY
ARABIANLIGHT
NIGERIANBONNY
11.2
0.08
5.06
15.0
9.32
25.2
44.6
FRACTIONS FROM 3 DIFFERENT CRUDESFRACTIONS FROM 3 DIFFERENT CRUDES
CHARACTERISTICS OF SOME CRUDE OILS
CHARACTERISTICS OF SOME CRUDE OILS
Viscosity,20 °C,cSt
Sulfur,%
Vanadium, ppm
Nickel, ppm
Asphaltenes, %
Conradson carbon,%
Arabianlight
9.2
1.8
15
5
0.7
5.1
Arabianheavy
40
2.8
30
10
2.7
Ekofisk
10
0.12
< 1
1.4
0.88
Nigerialight
6.7
0.11
2
6
0.08
0.86
Basrahheavy
57
3.58
54
22
8.3
Boscan
250000
5.2
1200
100
10.8
16.4
Ural
12.5
1.8
65
20
2.7
Refinery ProcessRefinery Process
Crude oil desaltingCrude oil desalting
Water and inorganic salts are removed in an electrostatic field.
The main purpose of crude oil desalting is to protect the refining process units against corrosion.
Atmospheric distillationAtmospheric distillation
Crude oil is a product with a very wide boiling range.In an atmospheric distillation column the fractionsboiling below 360°C are distilled off under reflux, and,according to boiling range, recovered as naphtha,kero, and gasoil type stocks. Atmospheric distillation
islimited to a maximum temperature of 360°C, becauseotherwise coking would start to occur, and this is notdesirable at this stage of crude oil refining.
Vacuum distillationVacuum distillation
In order to distill off a heavier cut, without exceeding
the 360°C temperature limit, a second distillation is
done under reduced pressure: the vacuum distillation.
The distillate fraction of the vacuum distillation unit is
the feedstock for a catalytic cracking unit
Catalytic crackingCatalytic cracking The main feedstock for a catalytic cracker is vacuum
gasoil. The cracking operation breaks large molecules into smaller, lighter molecules. The process runs at high temperatures, and in the presence of the appropriate catalyst (crystalline aluminum silicate).
Atmospheric residue, with a low metal and MCR content, can also be used as catalytic cracker feed, necessitating an adjustment of the catalyst type.
The main purpose of a catalytic cracker is to produce light hydrocarbon fractions, which will increase the refinery gasoline yield.
Additional streams coming from the catalytic cracker are light cycle oil (increases the gasoil pool) and heavy cycle oil (base stock for carbon black manufacturing). Both streams are also used in heavy fuel oil blending.
Catalytic hydrocrackingCatalytic hydrocracking
Some refineries have catalytic hydrocracking as a supplementary operation to catalytic cracking.
Catalytic hydrocracking further upgrades heavy aromatic stocks to gasoline, jet fuel and gasoil
type material. The heaviest aromatic fractions of a cat cracker are the normal feedstock for a hydrocracker.
Hydrocracking requires a very high investment , but
makes the refinery yield pattern nearly independent
from the crude oil feed.
VisbreakingVisbreaking
The feedstock of a visbreaker is the bottom productof the vacuum unit, which has an extremely highviscosity. In order to reduce that viscosity and toproduce a marketable product, a relatively mildthermal cracking operation is performed. Theamount of cracking is limited by the overrulingrequirement to safeguard the heavy fuel stability.The light product yield of the visbreaker (around20%) increases the blendstock pool for gasoil.
Coking (delayed coking, fluid coking, flexicoking)
Coking (delayed coking, fluid coking, flexicoking)
Coking is a very severe thermal cracking process, and
completely destroys the residual fuel fraction. The
yield of a coker unit is lighter-range boiling material,
which ultimately goes to the blending pool for the
lighter products, and coke, which is essentially solid
carbon with varying amounts of impurities. The
heavier distillate fraction of a coker can be used as
feedstock for a hydrocracker
Catalytic reforming and Isomerization
Catalytic reforming and Isomerization
Both processes are in fact catalytic reforming, and are intended to upgrade low octane naphta fractions of the crude distillation unit into high octane components for gasoline production. The type of catalyst and the operating conditions determine if the reforming is mainly to iso-paraffins, or to aromatics. The terminology “reforming” is generally used for the change to aromatics, while the change to iso-paraffins is referred to as “isomerization”. Isomerization is normally done on a lighter fraction(C5/C6), while reforming is done on the heavy naphtha fraction (C7 and heavier, up to 150°C).
AlkylationAlkylation
Process intended to increase the yield of valuable gasoline blend components. Alkylation is a catalyst steered combination reaction of low molecular weight olefins with an iso-paraffin to form higher molecular weight iso-paraffins. The feed to the alkylation unit is C3 and C4s from the catalytic cracker unit, and iso-butane.
HydrotreatingHydrotreating
A hydrotreating process is, as the name indicates, a process, which uses hydrogen to remove impurities from product streams, and replaces them with hydrogen. Hydrotreating is generally used to remove sulphur (very low sulphur limits in the specifications of gasoline and gasoil) and is then called hydro-desulphurization. It is a catalytic process. The process is generally used on kerosene and gasoil fractions. Residual hydro-desulphurization is an existing process, and is in theory feasible, but the economics are not favorable.
MeroxMerox
A merox unit is used on naphtha and kerosene streams. It is a catalytic process which is not intended to remove the sulphur from the stream, but to convert mercaptan sulphur type molecules (corrosive, and with a very obnoxious smell) into disulphide type molecules.
Modern RefineryModern Refinery
Atmospheric DistillationAtmospheric Distillation» ReformingReforming
Vaccum DistillationVaccum Distillation» Catalytic crackingCatalytic cracking» HydrocrackingHydrocracking» VisbreakingVisbreaking
DeasphaltingDeasphalting
Atmospheric distillationAtmospheric distillation
A
D
100T
GAS(3T)
KERO 11 T
ST. GASOLINE 16 T
GAS OIL 28 T
RESIDUE 42 T400 CST @ 50 deG C,S=3.1%
Vaccum distillationVaccum distillation
V
D
42TOFA.R
DISTILLATE 23.4T
18.6T
3000 cst @50degC,S=4.1%
Fluxing LGO
6.8T
25.4T
380 cst @50degC,S<4%
Vaccum distillation + FCCUVaccum distillation + FCCU
V
D
42TOFA.R
18.6T
3000 cst @50degC,S=4.1%
Fluxing(kERO)
2.0T
25.7T
380 cst @50degC,S<4%
23.4TFCCU
5.1T5.1T
6.9T
light gasoline
Heavy gasoline
1.4 THGO
3.7 TLGO
Vaccum distillation + FCCU + VBVaccum distillation + FCCU + VB
V
D
42TA.R 18.6T
3000 cst @50degC,S=4.1% 380 cst @50degC,S<4%
23.4TFCCU
5.1T
1.4 THGO
3.7 TLGO
5.1T
6.9T
light gasoline
Heavy gasoline
VIS BREAKER
2.8T Gas oil
.9TLGO
1.2T 1.2T
gas
gas15.3T
7000 cst@50degC,
Gas
AD
VD
Reforming
Visbreak.
Hydrocr.
Coking
FCC
DA
Naphta
GasolinesKeroseneDiesel oils
Heavy fuels SR 1
2
3
Gasolines
GasolinesKero,Diesel
Heavy fuels
H2, no HeavyFuels 4
AsphaltsHeavy fuels
REFINERY SCHEMESREFINERY SCHEMES
About Fuel oilAbout Fuel oil
Straight run marine gasoil and distillate
Straight run marine gasoil and distillate
Marine diesel type MDO are manufactured from kero, light, and
heavy gasoil fractions. For DMC type gasoil, up to 10–15% residual fuel can
be added.
Straight run IFO 380 mm2/s (at 50°C) This grade is made starting from the atmospheric
residue fraction (typical viscosity of about 800 mm2/s at 50°C) by blending with a gasoil fraction.
Straight run lower viscosity grade IFOs Blending to lower grade IFOs is done from the IFO
380 mm2/s (at 50°C) using a gasoil type cutterstock or with marine diesel.
Complex RefineriesComplex Refineries
The main marine fuel blending components from a Fluidized Bed Catalytic Cracking (FCC) type refinery with visbreaker are the same distillates as those from a straight run refinery (light and heavy diesel) as well as light cycle (gas) oil (LC(G)O) and heavy cycle oil (HCO) from the catcracker and visbroken residue from the visbreaker.
Atmospheric residue is used as feedstock for the vacuum unit and will only seldom be available for fuel blending.
Complex RefineriesComplex RefineriesMarine gasoil (MGO/DMA) A new blend component has appeared — LC(G)O
(light cycle (gas) oil) — which contains about 60% aromatics. Due to the high aromatic nature of LC(G)O, the density of a marine gasoil blended with LC(G)O will be higher than when using gasoil of an atmospheric distillation type refinery. No performance or handling differences with atmospheric type gasoil
Distillate marine diesel (MDO/DMB) Distillate marine diesel typically has a lower cetane
number than marine gasoil, and a higher density. With the production slate of a catalytic cracking refinery, distillate marine diesel therefore contain a higher percentage of LC(G)O than marine gasoil.
Complex RefineriesComplex RefineriesBlended marine diesel (MDO/DMC) With atmospheric type refining, blended marine diesel (MDO/DMC) can
contain up to 10% IFO with either marine gasoil (MGO/DMA) or distillate marine diesel (MD)/DMB). With complex refining, blended marine diesel (MDO/DMC) no longer corresponds to a specific composition and extreme care needs be used when blending this grade to prevent stability and/or combustion problems.
IFO-380 This grade is usually manufactured at the refinery and contains
visbroken residue, HCO and LC(G)O These three components influence the characteristics of the visbroken IF-380 Vacuum distillation reduces the residue yield to about 20% of the crude feed, unavoidably leading to a concentration of the heaviest molecules in this fraction. Visbreaking converts about 25% of its vacuum residue feed into distillate fractions. This means that about 15% of the original crude remains as visbroken residue. The asphaltene1, sulphur and metal content in visbroken residue are 3 to 3.5 times higher than in atmospheric residue. Visbreaking affects the molecular structure: molecules are broken thermally and this can deteriorate the stability of the asphaltenes.
Complex RefineriesComplex Refineries HCO (typical viscosity at 50°C: 130 mm2/s) contains
approximately 60% aromatics, and is a high-density fraction: the density at 15°C is above 1 kg/l (typically 1.02). It is the bottom fraction of the FCC unit. The catalytic process of this unit is based on an aluminum silicate. Some mechanical deterioration of the catalyst occurs in the FCC process, and the resulting cat fines are removed from the HCO in the refinery. This removal however, is not 100% efficient, and a certain amount (ppm level) of cat fines remains in the HCO, and from there end up in heavy fuel blended with HCO. The aromaticity of HCO assists in ensuring optimum stability for the visbroken fuel blend.
LC(G)O (typical viscosity at 50°C: 2.5 mm2/s) has the same aromaticity as HCO, but is a distillate fraction of the FCC unit, with a distillation range comparable to that of gasoil. With a typical density of 0.94 kg/l at 15°C, it is used to fine-tune the marine heavy fuel oil blending where generally a density maximum limit of 0.9910 kg/l has to be observed.
CHEMICAL COMPOSITIONCHEMICAL COMPOSITION
RESIDUE OR HEAVY FUEL OILRESIDUE OR HEAVY FUEL OIL
ASPHALTENESASPHALTENESMALTENESMALTENES
"OIL""OIL"
"RESINS""RESINS"
SATURATED SATURATED AROMATICAROMATIC
ComponentsComponents
OILOIL» Molecular weight < 800 Molecular weight < 800 » Mixture of paraffins,naphthenes & aromaticMixture of paraffins,naphthenes & aromatic
RESINRESIN» Molecular weight ~ 1000Molecular weight ~ 1000» condensed aromatics with aliphatic ring chainscondensed aromatics with aliphatic ring chains
ASPHALTENESASPHALTENES» Molecular weight between 1000 ~ 2000Molecular weight between 1000 ~ 2000» Highly condensed aromaticsHighly condensed aromatics
Conclusions-Macro levelConclusions-Macro level
Fuel oil yield dropFuel oil yield drop More of fluxingMore of fluxing Less of lighter componentsLess of lighter components More complications due to types of More complications due to types of
crudescrudes
Conclusions-Micro levelConclusions-Micro level
Increased densityIncreased density Increased ViscosityIncreased Viscosity Increased carbon residueIncreased carbon residue Increased asphaltenesIncreased asphaltenes Increased sulphurIncreased sulphur Reducing heating value ????Reducing heating value ???? Increasing trace metals ????Increasing trace metals ???? InstabilityInstability IncompatibilityIncompatibility
Key Quality IndicatorsKey Quality Indicators Specific gravitySpecific gravity
» Weight per unit volumeWeight per unit volume
Flash pointFlash point» Safe operating temperatureSafe operating temperature
Viscosity(Kinematic)Viscosity(Kinematic)» Resistance to flowResistance to flow
Pour PointPour Point» Lowest Flowable temperatureLowest Flowable temperature
Sulphur contentSulphur content» % wt of Sulphur in Fuel oil% wt of Sulphur in Fuel oil
Calorific valueCalorific value» Heat per unit weightHeat per unit weight
Key Quality IndicatorsKey Quality Indicators
Ash ContentAsh Content» Inorganic & non combustible matterInorganic & non combustible matter
CCAICCAI» Ignition qualityIgnition quality
Conradson carbon residue(CCR)Conradson carbon residue(CCR)» Residual matterResidual matter
HFO CHARACTERISTICSHFO CHARACTERISTICS
PARAMETER A.D V.D FCCU VB
DENSITY 0.973 0.978 0.985 1.018
KV @ 50 DEG C 380 450 450 450
KV @ 100 DEG C 35 38 40 40
SULPHUR 3~4 3.5~4 3.8~4 3.9~4
ASPHALTENES % 2.7 3.3 5 6
CCR % 7.5 8.5 11.5 11~20
SODIUM ppm 15 15~40 15~40 25~60
VANADIUM ppm 35 40~80 70~110 80~150
NICKEL ppm 10 10~50 30~60 35~70
Effects of quality parameters on engine performance
Effects of quality parameters on engine performance
ViscosityViscosity
Injection CharacteristicsInjection Characteristics» Droplet size of 10-100 micronsDroplet size of 10-100 microns» 10-15 Cst at nozzle tip10-15 Cst at nozzle tip
Injector pump wearInjector pump wear Fuel flow propertiesFuel flow properties Preheating to correct viscosity at nozzle Preheating to correct viscosity at nozzle
tiptip Certain cases upto 150 deg CCertain cases upto 150 deg C
FUELFUEL INJ VISC INJ VISC INJ VISCINJ VISC 13 CST13 CST 17 CST 17 CST
120 120 100 100 91 91160 160 112 112 104 104
170170 115 115 107 107 180180 119 119 109 109 200200 121 121 111 111 220220 123 113 123 113
Ignition Characteristics(CCAI)Ignition Characteristics(CCAI)
Shell proposedShell proposed Calculated Carbon Aromaticity IndexCalculated Carbon Aromaticity Index D-140.7LOG LOG (V+.85)-80.6D-140.7LOG LOG (V+.85)-80.6
» D:Specific Gravity @ 15deg CD:Specific Gravity @ 15deg C» V:Viscosity @ 50 deg CV:Viscosity @ 50 deg C
Nomographic method most suitableNomographic method most suitable Max acceptable around 900Max acceptable around 900 BP's CCI also usedBP's CCI also used Diesel IndexDiesel Index
» (API gravity*aniline point deg F)/100 (API gravity*aniline point deg F)/100
SulphurSulphur
SOx + water ----> Sulphuric acidSOx + water ----> Sulphuric acid Temp drops below dew pointTemp drops below dew point Corrosion Corrosion Cold corrosionCold corrosion Control of temperaturesControl of temperatures LubricantLubricant
Conradson Carbon residueConradson Carbon residue
Formation carbon depositsFormation carbon deposits» "Trumpets""Trumpets"
Injection characreristics are alteredInjection characreristics are altered» lower the speed more the tolerance for CCRlower the speed more the tolerance for CCR
Indicative of apshaltene contentIndicative of apshaltene content» CCR% = 2* asphaltenesCCR% = 2* asphaltenes
Ash Ash
Na,V,Si,Fe compoundsNa,V,Si,Fe compounds» Hot CorrosionHot Corrosion» At melting points they form depositsAt melting points they form deposits» Hard At hot spotsHard At hot spots
Cooler valve seats etcCooler valve seats etc
Calorific ValueCalorific Value
heat energy containedheat energy contained Emperical formulaeEmperical formulae
» HSDHSD GCV(btu)=1.8(12400-2100d*d)GCV(btu)=1.8(12400-2100d*d) d-Spec gravity @ 60 deg Fd-Spec gravity @ 60 deg F
FUEL OILSFUEL OILS» GCV=80.84*C +289.2H+22.24SGCV=80.84*C +289.2H+22.24S
C,H,S % OF carbon,hydrogen & SulphurC,H,S % OF carbon,hydrogen & Sulphur
Calorific ValueCalorific Value
Specific Energy (Gross) MJ/kg
Qg = (52.190 - 8.802 p2 10-6) [1 - 0.01 (x+y+s)] + 9.420 (0.01s)
Specific Energy (Net) MJ/kg
Qn = (46.704 - 8.802p210-6 + 3.167p10-3) [1-0.01(x+y+s)] + 0.01 (9.420s - 2.449x)
p = the density at 15 °C, kg/m³x = the water content, % (m/m)y = the ash content, % (m/m)s = the sulphur content, % m/m
Typical % of C,H,STypical % of C,H,S
FUEL CARBON HYDROGEN SULPHUR
FO 85.2 11.5 3.3
LSHS 87 12.3 0.7
LDO 86.4 12.7 0.9
HSD 86 13.5 0.5
Storage & HandlingStorage & Handling
MODEL OF ASPHALTENE MOLECULEMODEL OF ASPHALTENE MOLECULE
S
CH2
CH3
CH2
CH3
CH3
CH
CH2
CH2
CH3
CH2CH2CH3
CH2CH2
S
S
CH2
CH2
CH3
CH2
S
CHCH2
CH2
CH3
CH2
CH2
CH3
CH
CH2
CH2
CH3
CH2 CH2CH3
N
CH3
CH2
CH3
CH3
CH2
CH3
CH3
CH3
CH2CH2
O
CH2
S
CH2
CH2
CH2
CH
CH2
CH2
CH3CH3
CH2CH3
CH3
CH3
ASPHALTENES CHARACTERISTICS
ASPHALTENES CHARACTERISTICS
Polycondensed aromatic structures with few Polycondensed aromatic structures with few alkyl chainsalkyl chains
Contains hetero-atoms: S, N, OContains hetero-atoms: S, N, O
Contains metals: V, Ni, NaContains metals: V, Ni, Na
Not soluble in oilNot soluble in oil
Size of the micellar unit: 8 - 20 ASize of the micellar unit: 8 - 20 A
Cannot boil even under reduced pressureCannot boil even under reduced pressure
Molecular structure depends on crude oil Molecular structure depends on crude oil originorigin
RESINS CHARACTERISTICSRESINS CHARACTERISTICS
Chemical structure close to asphaltenes Chemical structure close to asphaltenes
structure but:structure but: LONGER ALKYL CHAINSLONGER ALKYL CHAINS
LESS CONDENSED RINGSLESS CONDENSED RINGS
MORE SOLUBLE IN OILMORE SOLUBLE IN OIL
Molecular structure depends on crude oil Molecular structure depends on crude oil
originorigin
Presence necessary to provide a good Presence necessary to provide a good
stability to the fuelstability to the fuel
HEAVY FUEL OILSHEAVY FUEL OILS
DISPERSED AND STABLE FLOCULATEDResins ensure seperation of heavy asphaltene molecules. Flocculated Asphaltene molecules tend to form sludge and settle at the bottom of the tank.
InstabilityInstability
Asphaltenes "peptized" by resinsAsphaltenes "peptized" by resins Instability occurs when this peptization Instability occurs when this peptization
breaksbreaks Apshaltenes "flocculate"Apshaltenes "flocculate" Precipitation occursPrecipitation occurs Filter clogging,Overloading of Filter clogging,Overloading of
Centrifuge,deposits in tanksCentrifuge,deposits in tanks "No more a major problem""No more a major problem"
IncompatibiltyIncompatibilty
When 2 different source FO's mixWhen 2 different source FO's mix Effects will be similar to InstabilityEffects will be similar to Instability ASTM D 4740 "spot test" ASTM D 4740 "spot test" "Avoid mixing FO's from different "Avoid mixing FO's from different
refineries"refineries"
Pre-PreparationPre-Preparation
SettlingSettling PurificationPurification ClarificationClarification HomogenisationHomogenisation
» AdditivesAdditives» CostlyCostly» Uncertain efficiencyUncertain efficiency
FilterationFilteration
ISO 8217 FUEL STANDARD FOR MARINE DISTILLATE FUELS
ISO 8217 FUEL STANDARD FOR MARINE DISTILLATE FUELS
----0.300.30Max%m/mMICRO CARBON RESIDUE
ON 10% DIST. BOTTOMS
-------16Max°CCLOUD POINT
660--Max°CPOUR POINT, SUMMER
00-6--Max°CPOUR POINT, WINTER
60606043Min°CFLASH POINT
14.011.06.005.50Maxmm2/s
----1.501.40Minmm2/sVISCOSITY @ 40°C
920.0900.0890.0--Maxkg/mDENSITY @ 15°C
DMCDMBDMADMXLIMITSUNITSCHARACTERISTIC
ISO 8217 FUEL STANDARD FOR MARINE DISTILLATE FUELS
ISO 8217 FUEL STANDARD FOR MARINE DISTILLATE FUELS
25------Maxmg/kgALUMINIUM & SILICON
100------Maxmg/kgVANADIUM
2.02.01.51.0Max%m/mSULFUR
----ClearClear----VISUAL INSPECTION
--354045Min--CETANE NUMBER
0.30.3----Max% V/VWATER
0.10------Max%m/mTOTAL SEDIMENT EXISTENT
--0.07----Max%m/mSEDIMENT BY EXTRACTION
0.050.010.010.01Max%m/mASH
2.500.30----Max%m/mMICRO CARBON RESIDUE
ISO FUEL STANDARD 8217, 1ST REVISION 1996, FOR MARINE RESIDUAL FUELS
ISO FUEL STANDARD 8217, 1ST REVISION 1996, FOR MARINE RESIDUAL FUELS
RMK 55
DENSITY @ 15°C kg/m Max 975 981 981 985 991 991 991 991 1010 991 1010 - 991 1010 -
VISCOSITY @ 100°C mm2/S Max 10 10 10 15 25 25 35 35 35 45 45 45 55 55 55
APPROX VISC. @ 50°C * mm2/s 50 50 50 100 225 225 390 390 390 585 585 585 810 810 810FLASH POINT °C Min 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60POUR
POINT, WINTER °C MAX 0 24 24 30 30 30 30 30 30 30 30 30 30 30 30
POUR POINT,
SUMMER °C Max 6 24 24 30 30 30 30 30 30 30 30 30 30 30 30MCR % m/m Max 10 10 14 14 15 20 18 22 22 22 22 -- 22 22 --ASH % m/m Max 0.1 0.1 0.1 0.1 0.1 0.15 0.15 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2
WATER % V/V Max 0.5 0.5 0.5 0.8 1 1 1 1 1 1 1 1 1 1 1SULFUR % m/m Max 3.5 3.5 3.5 4 5 5 5 5 5 5 5 5 5 5 5
VANADIUM mg/kg Max 150 150 300 350 200 500 300 600 600 600 600 600 600 600 600
ALUMINIUM &
SILICON mg/kg Max 80 80 80 80 80 80 80 80 80 80 80 80 80 80 80TOTAL
SEDIMENT POT % m/m Max 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1
RML 55RMH 45 RMK 45 RML 45 RMH 55RMF 25 RMG 35 RMH 35 RMK 35RMB 10 RMC 10 RMD 15 RME 25CHARACTERISTIC UNITS LIMIT RMA 10
ISO 8217:1996
Revised ISO 8217 (likely early 2006)
Al+ Si ISO 10478 (ICP and atomic absorption)
ISO 10478 (equivalent to IP 377) is the reference method
New : IP 501 New : IP 470 Ca Not
included IP 501 (ICP)
IP 470 (atomic absorption) Zn Not
included IP 501 (ICP)
IP 470 (atomic absorption) P Not
included IP 501
IP 500 (UV spectrometry) V ISO 14597
(X-ray) IP 501 (ICP)
IP 470 (atomic absorption)
Revision of ISO 8217Revision of ISO 8217
Release end 2005, early 2006 ?Release end 2005, early 2006 ?
Main changesMain changes : : Fuel grades basis viscosity at 50 °C instead of 100 °CFuel grades basis viscosity at 50 °C instead of 100 °C
RMC 10 no longer existsRMC 10 no longer exists
RMA 30 , RMB 30 and RMD 80 : lower max. densityRMA 30 , RMB 30 and RMD 80 : lower max. density
Water content : max. 0.5 v/v % for all gradesWater content : max. 0.5 v/v % for all grades
Ash content : Ash content : Fuel grades with a max ash of 0.10 m/m % : no changesFuel grades with a max ash of 0.10 m/m % : no changes
Fuel grades with a max ash of 0.20 m/m % : new max limit : 0.15 m/m %Fuel grades with a max ash of 0.20 m/m % : new max limit : 0.15 m/m %
Sulphur content : as of RME 180 : 4.5 m/m % max.Sulphur content : as of RME 180 : 4.5 m/m % max.
Limits for used lubricating oils (ULO): Limits for used lubricating oils (ULO): A fuel shall be considered to be A fuel shall be considered to be free of ULO if one or more of the elements Zn, P and Ca are below or at free of ULO if one or more of the elements Zn, P and Ca are below or at the specified limits (resp. 30/15/15 mg/kg)the specified limits (resp. 30/15/15 mg/kg)
SN
1 mg/KoH/g
2 % wt.
3 kg/m3
4 O C
5 cst
6 % wt.
7 % wt.
8 % vol.
9 O C
10 ppm
11 ppm
12 ppm
13 K cal/kg
14 K cal/kg
15 % wt.
16 % wt.
17 ppm
18 ppm
19 ppm
20 ppm
P:30
Pb
Fe
ICP/AAS
ICP/AAS
ICP/AAS
Ni
NCV
Asphaltenes Content
Aluminium ICP/AAS
P:7
IP 143
+3
65
2
Pour point
Vanadium
Sodium
D-97
ICP/AAS
ICP/AAS
D-95
RCR
1
Sediment
2
GCV P:7
D:524
D-482
0.10
Si ICP/AAS
973.3
Total sulphur D 4294 3.60
Water content
Kinematic viscosity at 50 deg.C D-445
Density at 15 deg.C D-1298
Flash point (PMCC) D-93
Ash
Characteristics Unit
NilAcidity, inorganic D-974
ResultMethod of Test [P] of IS:1448 / ASTM
11.6
343
84
0.06
5
1
7
10150
9566
4
0
FUELFUEL VISC VISC Temp cStTemp cSt
40 40 720 720 100 100 33 33
110110 24 24 115115 20 20 120120 18 18 125125 15 15 130 130 1313