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Clean
Oil Reduces Engine Fuel Consumption
By
JIM FITCH
Noria Corporation
Over
the last couple of weeks, we have received several
phone calls
and emails asking
us about fuel savings and clean oils. After discussing
this subject with other experts in the field as well,
we came across this great article from Mr. Jim Fitch
of Noria and wanted to share this with all of our
subscribers. Thanks Mr. Fitch for such great insight
on this subject.
In the July-August issue of Machinery Lubrication
magazine, my column discussed the important role of
lubrication on energy conservation and environmental
protection. The more I delve into this subject, the
more I discover the pronounced impact lubrication has
on energy and the environment. A case in point is the
impact of clean oil on fuel consumption and emission
in engines.
There
are many ways that a lubricant could fail to deliver
fuel-efficient engine performance. Many of these are
due to formulation issues as opposed to transient properties
of the lubricant in service. For instance, there were
significant advances in energy conservation when switching
from GF-2 to GF-3 (international quality designation
for gasoline engine lubricants) in 2001
(Figure
1. GF-3 and GF-2 Comparison Diagram ).
When a lubricant degrades, it forms reaction products
that become insoluble and corrosive. So too, the original
properties of lubricity and dispersancy can become
impaired as the lubricant ages and additives deplete.
Much has been published about the risks associated
with overextended oil drains and the buildup of carbon
insolubles from combustion blow-by.
However,
surprisingly little has been said about the impact
of fine abrasives in a lube oil as it relates to
fuel economy over the engine’s life. One can
imagine numerous scenarios in which solid abrasives
suspended in the oil could diminish optimum energy
performance. Below is a list of several scenarios:
- Antiwear Additive Depletion. High
soot load of crankcase lubricants has been reported
to impair the performance of ZDDP antiwear additives.
Some researchers believe that soot and dust particles
exhibit polar absorbencies, and as such, can tie-up
the AW additive and diminish its ability to control
friction in boundary contacts (cam nose, ring/ liner,
etc.).
- Combustion
Efficiency Losses. Sooner or later, wear from abrasive
particles and deposits from carbon and oxide insolubles
will interfere with efficient combustion in an
engine. Valve train wear (cams, valve guides, etc.)
can impact timing and valve movement. Wear of rings,
pistons and liners influences volumetric compression
efficiency and combustion blow-by resulting in
power loss. As has been previously reported in
this magazine, particle-induced wear is greatest
when the particle sizes are in the same range as
the oil film thickness (Figure
2). For diesel and
gasoline engines, there are a surprising number of
laboratory and field studies that report the need
to control particles below ten microns. One such
study by GM concluded that, “controlling particles
in the 3 to 10 micron range had the greatest impact
on wear rates and that engine wear rates correlated
directly to the dust concentration levels in the
sump.” 1
- Frictional Losses. When hard
clear- ance-size particles disrupt oil films, including
boundary chemical films, increased friction and wear
will occur. One researcher reports that 40 to 50
percent of the friction losses of an engine are attributable
to the ring/cylinder contacts, with two-thirds of
the loss assigned to the upper compression ring. 2 It
has been documented that there is an extremely high
level of sensitivity at the ring-to-cylinder zone
of the engine to both oil- and air-borne contaminants.
Hence, abrasive wear of the ring/cylinder area of
the engine translates directly to increased friction,
blow-by, compression losses and reduced fuel economy.
- Viscosity Churning Losses. Wear
particles contribute to oxidative thickening of aged
oil. High soot load and/or lack of soot dispersancy
can also have a large impact on oil viscosity increases.
Viscosity-related internal fluid friction not only
increases fuel consumption but also generates more
heat that can lead to premature degradation of additives
and base oil oxidation.
Stiction Losses. Deposits in the combustion
chamber and valve area can lead to restriction movements
in rings and valve control. When hard particle contamination
agglomerates with soot and sludge to form adherent deposits
between valves and guides, a tenacious interference,
called stiction, results. Stiction causes power loss.
It causes the timing of the port openings and closings
to vary, leading to incomplete combustion and risk of
backfiring. Advanced phases of this problem can lead
to a burned valve seat. 2 Power
Losses from Wear of Cummins Engines
Figure 3 shows an example of how increased engine wear, in this case due to overextended
oil drains, contributes to power loss in the engine. At 2100 rpm, the severely
worn engine horsepower at the wheels decreased from 365 hp to less than 300 hp
(18 percent). Loss of horsepower translates directly to losses in fuel economy.
3
A
bus engine fuel consumption study by G. Andrews,
et al. of the University of Leeds (Table
1), provides
evidence of the benefit associated with cleaner oil
on fuel economy in an actual road trial. 4 It was noted
that the Cummins engine’s fuel efficiency increased
2 percent to 3 percent when a six-micron by-pass filter
was used along with a full flow filter. The study spanned
50,000 miles of service. The fuel consumption was calculated
based on detailed fuelling records from the fleet.
In a similar study reported by the same authors using
by-pass filtration, a 5 percent to 8 percent reduction
in fuel consumption was achieved on a 1.8 liter Ford
passenger car IDI diesel engine.
A
study reported by J. Fodor and F. Ling of the Research
Institute of Automotive Industry-Budapest and published
in Lubrication Engineering magazine (Table
2) found
a sharp improvement in fuel economy in a six-cylinder
diesel engine fitted with improved filtration. By reducing
oil contamination by 98 percent, not only was a nearly
5 percent reduction in fuel consumption achieved but
wear and friction were reduced by 93 percent and 2.9
percent respectively. 5
Waste Stream Emissions
When the engine consumes oil, due primarily to contaminant-induced wear, oil
enters the combustion chamber, burns with the fuel, and is pushed out with exhaust
gases as particles and volatile hydrocarbons. New mineral-based lubricants have
a more volatile light-end fraction and are more prone to hydrocarbon emissions.
The level of exhaust emissions increases considerably over time corresponding
to engine wear and deposit formation in the combustion zone. This leads not only
to greater concentration of exhaust particulates, but also to a higher percentage
that are unburned hydrocarbon, a by-product of oil consumption.
Unlike a new engine, the lubricating oil is a dominant
contributor to particulate matter (PM) emissions in
aged engines. The obvious strategy to control/reduce
hydrocarbon emissions is to reduce oil consumption.
...
...
This, of course, points to a strategy of reducing
abrasion and wear. According to projections by
Barris of Donaldson Co. (Figure
4), after 12,000
hours of service, an off-road diesel engine can
produce nearly six times more exhaust emissions
due to wear associated with particles and other
causes.6
Crankcase Oil Particle Counts
Good environmental stewardship is everyone’s responsibility. We all benefit
from cleaner air and a safer environment. In addition, the financial impact
that comes from reduced fuel consumption alone can be substantial. Perhaps
it’s time for OEMs and users alike to begin revisiting contamination
control practices, including filtration, associated with internal combustion
engines.
If
clean oil is important to control wear, reduce fuel
consumption and emissions, perhaps it’s
also time for users to begin asking their laboratories
to begin reporting particle counts and ISO Codes of
used crankcase oils. Remember, if it’s important,
we measure it - correctly. What gets measured gets
done.
Jim Fitch (Noria Corp.)
References
- Staley,
D.R. (1988). "Correlating Lube Oil
Filtration Efficiencies with Engine Wear". SAE
Truck and Bus Meeting and Exposition (Paper 881825).
- Madhavan,
P.V. and Needelman, W.M. (1988). "Review
of Lubricant Contamination and Diesel Engine Wear". SAE
Truck and Bus Meeting and Exposition (Paper 881827).
- McGeehan,
J. (2001, September-October). Uncovering the Problems
with Extended Oil Drains. Machinery
Lubrication magazine (www.machinerylubrication.com),
pp. 24-29.
- Andrews,
G.E., Li, H., Jones, M.H., Hall, J. Rahman, A.A.
and Saydali, S. (2000). "The Influence
of an Oil Recycler on Lubricating Oil Quality with
Oil Age for a Bus Using In-Service Testing". SAE
2000 World Congress (Paper 2000-01-0234).
- Foder,
J. and Ling, F.F. (1985, October). Friction Reduction
in an IC Engine through Improved Filtration and
a New Lubricant Additive. "Lubrication Engineering".
pp. 614-618.
- Barris,
M.A. (1995). "Total Filtration: The Influence
of Filter Selection on Engine Wear, Emissions and Performance".
SAE Fuels and Lubricants (Paper 952557).
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