Read some people’s posts to web discussions groups
and you’d think that water injection is the bodgiest of the bodgy mods that it’s
possible to have on a car. You know – why don’t you get real and go buy an
intercooler? Or, I guess it’s OK if you need some kind of fix for that
major tuning problem you must have...
But the idea that water injection systems are
band-aid solutions for technical incompetents would startle some of the best
engineers that have ever worked on engines – from pioneers of the combustion
engine nearly 80 years ago, to those designing WWII fighter aircraft engines, to
much more recent World Rally Cars.
So let’s set the record straight... but first, a
timeline of water injection application.
Earliest Work
Water injection was first experimented with in the
1930s. At the time it was discovered that detonation could initially be
prevented by enriching the air/fuel ratio. As cylinder pressures rose still
further and that approach ceased being effective, the injection of water into
the intake air stream was found to prevent detonation.
Interestingly, the detonation remained suppressed,
even if the air/fuel ratio was then leaned-out. This occurred because the
excess fuel was being used to cool the combustion process. When water replaced
fuel in performing this function, less fuel was then required.
Writing in The High Speed Combustion
Engine, Sir Harry Ricardo and J G G Hempson said of engine that they were
using for experimentation (it had a compression ratio of 7:1, was supercharged
and used 87 octane fuel):
...the engine was run on an economical mixture,
ie about 10 per cent weak, and supercharge applied until the first incidence of
detonation, which occurred when BMEP* reached 168 psi. The mixture strength was
then increased, step by step, and more supercharge applied until the same
intensity of detonation was recorded; this process was continued until a point
was reached at which no further enrichment was effective. In fact, after about
60 per cent excess fuel, not only did further enrichment have no effect but
there was even some indication that it increased the tendency to
detonate.
(*BMEP = Brake Mean Effective Pressure - that is,
that is the average pressure on the piston during the four-stroke working cycle,
measured at the flywheel. This measurement is a good indicator of engine output
torque.)
A finely pulverized water spray was then
delivered to the induction pipe, which served to suppress detonation, in part by
the intercooling it provided, and in part by the influence of steam as an
anti-detonant, and so allowed of further supercharging. This was continued
progressively, admitting just sufficient water at each stage to ward off
detonation, until a BMEP of 290 psi was reached
[indicative of approximately
a 73 per cent increase in torque!]
, which was found to be the limit of the
dynamometer.
At the same time it was noted, that with the
addition of water, the influence of steam as an anti-knock allowed of the
fuel/air ratio being much reduced.... In fact, with water injection, no
appreciable advantage was found from the use of an over-rich fuel/air
mixture.
With water
[injected]
alone, however,
evaporation of the water was by no means complete even at the highest degree of
supercharge, and it was found more effective to add a substantial proportion of
some volatile alcohol, such as methanol, in order to increase the volatility...
Methanol, however, is very prone to pre-ignition and, on this score, it is
unwise to use too great a concentration; the safe limit appears to be a 50/50
methanol/water mixture.
World War II
During World War II, water injection was
extensively used on both Allied and Axis aircraft. These aircraft were all
powered by piston engines; most were supercharged. In the 1940s NACA (the
predecessor to NASA) reported extensively on water injection experiments.
In NACA report No 756, The Induction of Water
to the Inlet Air as a Means of Internal Cooling in Aircraft-Engine
Cylinders, the engineers conducted tests over the period December 1941 to
March 1942. The tests were carried out on a single cylinder 202 cubic inch (3.3
litre) air-cooled engine with a compression ratio of 7:1, a fixed spark advance
of 20 degrees, an engine speed of 2000 rpm and an inlet air temperature of 250
degrees F (121 degrees C!).
This is some of what they had to say:
Water as an internal coolant is of interest as
a means of suppressing knock in short bursts of high power output, that is,
during take-off and during combat manoeuvres. In these cases it would probably
be necessary to use a water-alcohol mixture to prevent freezing. Such a
procedure would permit high powers during take-off with a fuel of a low octane
number.
...it is estimated that for a water-fuel ratio
of 0.6, an engine requiring a fuel of 100-octane number could operate
satisfactorily on a fuel of 80-octane number... The data indicate that the
permissible decrease in octane number for moderate quantities of water injected
is considerable.
The temperature of the rear spark-plug bushing
at a fuel-air ratio of 0.067
[ie air/fuel ratio of 14.9:1]
showed a
change of only 18 degrees F as the permissible indicated mean effective pressure
[IMEP*]
was increased from 180 to 305 through the induction of water at a
water-fuel ratio of 0.6.
[However]
the exhaust-valve-guide temperature
showed a considerable increase as the maximum inlet pressure was increased with
the water injection. This increase is probably caused by the increased mass flow
of the gases passing around the exhaust valve and possibly also through
increased gas leakage past the guide, resulting from the higher exhaust
pressures that occurred.... The temperature of the head between the valves showed
a noticeable decrease for the higher values of water-fuel ratio, even though the
engine power was increased.
(*IMEP = Indicated Mean Effective Pressure - that
is, that is the average pressure on the piston during the four-stroke working
cycle. This measurement is a good indicator of engine torque, minus frictional
losses.)
With the air/fuel ratio kept at a constant 11:1,
on the test engine the maximum inlet manifold pressure rose from -3 psi with no
water injected, to 1.5 psi with a water/fuel ratio of 0.5, to 7 psi with a
water-fuel ratio of 1.0, to 8 psi with a water-fuel ratio of 1.5. Remember, this
is on 80-octane fuel and 121 degree C inlet air temp....
The paper said in summary:
Investigation of water induction in a
single-cylinder engine over a range of fuel-air ratios from 0.05 to 0.12
[20:1 – 8.3:1 air/fuel ratios]
indicate the following
conclusions:
-
Water injection allowed a fuel to be operated
above its normal maximum permissible performance limits.
-
Water injection allowed a fuel to be operated
at a higher indicated mean effective pressure, with a lower indicated specific
fuel consumption, or with both, than was permitted without an internal
coolant.
-
Water injection had a marked cooling effect on
the engine head and cylinder. The exhaust-valve guide was the only point on the
head at which the temperature showed a tendency to increase with indicated mean
effective pressure. The temperature was less, however, than that obtained with a
straight
[higher octane]
fuel permitting an equivalent
power.
-
Water injection showed no advantage in fuel
economy when the fuel was operated well below its maximum permissible
performance limits.
-
Water injection might be a disadvantage if the
engine cooling affects are carried to an extreme and cause crankcase-oil
dilution. Operation at normal engine and crankcase-oil temperatures should
minimize crankcase-oil dilution.
Another NACA paper, this time produced in August
1945, is Effect of Water-Alcohol Injection and Maximum-Economy Spark Advance
on Knock-Limited Performance and Fuel Economy of a Large Air-Cooled
Cylinder.
Using a water/alcohol solution consisting of 25
per cent ethyl alcohol, 25 per cent methy alcohol and 50 per cent water, the
following results were achieved:
-
The knock-limited power at an engine speed of
2100 rpm was increased as much as 88 per cent by operation at a fuel-air ratio
of 0.06
[16.6:1 AFR]
and a coolant-fuel
[ie water-fuel]
ratio of
0.4.
-
An increase in the coolant-fuel ratio from 0.2
to 0.4 was 2.5 times as effective in raising the knock-limited indicated mean
effective pressure
[IMEP]
at a fuel-air ratio of 0.075
[13.3:1
AFR]
as an increase in the coolant-fuel ratio from 0.0 to
0.2.
1950s
In the Aviation Machinist’s Mate 3,
published in 1957 by the US Department of the Navy as a training text, water
injection on piston aircraft is further discussed.
....the carburettor or fuel injection system
supplies an excessively rich mixture for
[internal]
cooling purposes at
high-power operation. A leaner mixture would produce more power but the
additional fuel is required to prevent overheating and detonation. With the
injection of water into the induction system, the mixture may be leaned-out to a
rich best-power fuel-air ratio, and the vaporization of the fluid then provides
the cooling formerly provided by the excess fuel. Operating at their best-power
mixtures, the engines will develop more power even though the rpm and manifold
pressure settings remain unchanged.
In most installations water cannot be used
alone because of the water freezing in the tank or lines either on the ground or
in the air, and alcohol is therefore added to the water. The mixture is
generally 50 percent water and 50 percent alcohol; however, in cold weather
operation, 60 percent alcohol may be used.
By the use of water injection, power may be
increased from 15 to 25 percent, thus the effective
Performance Number of grade 115/145 fuel may be raised to 168/182.
The water injection system discharges the
water/alcohol mixture into the induction system and, at the same time, causes a
leaner air/fuel ratio and an increase in manifold pressure.
Falling into Disrepute
Over the next few decades water injection was
largely dropped in high performance piston engine applications, although the
very first production turbo car – the 1962 Oldsmobile Jetfire Turbo Rocket - had
water injection fitted as standard. It used a 215 cid aluminium V8 with 10.25:1
compression ratio and 5 psi boost from a Garrett T5. (See The Early Days of Turbo - Part Four
for more on this fascinating car.)
To avoid detonation, a 50:50 mix of distilled
water and methyl alcohol (ie methanol) was injected between the carburettor and
turbo at times of high engine load.
It is said that, depending on driving style, the
content of this 4.7-litre reservoir could be consumed in anywhere from 3600 to
360 kilometres! The reservoir was meant to be refilled only with the premixed
'Turbo Rocket Fluid' available from Oldsmobile dealers. However, many owners
chose to make their own concoction using plain tap water.
In this period water injection kits were also
available for naturally aspirated cars, however the kit manufacturers often made
wild claims about resulting fuel economy benefits – perhaps the start of a
public disenchantment with the idea of water injection.
Turbo kits of the 1970s often used water injection
– off-the-shelf intercoolers were difficult to get and with only very few
original equipment turbo road cars available, the engineering of these turbo
cars was often rough and they drove badly. The water injection kits fitted to
these cars – often comprising just a windscreen washer pump and a nozzle – were
vastly cruder than the systems being used in aircraft thirty years before.
Motorsport
In 1983 Renault started using water injection on
their ~550hp turbocharged 1.5-litre F1 engine. The system used a 12-litre tank
and a dedicated control unit. An electric pump, pressure regulator and pressure
sensor were used. The system was triggered into action when manifold pressure
exceeded 2.5 Bar (36 psi). It was said that the inlet air temperature reduction
on these cars was 10-12 degrees C, dropping the intake air temp from around 60
to 50 degrees C.
In 1983 Ferrari also adopted water injection on
their F1 engines. However, the water was added in a unique manner, being
emulsified within the fuel itself before the fuel/water combination was
injected. Apparently the water/fuel ratio was about 0.1:1.
Up until a few years ago (when it was banned),
most World Rally Championship cars used water injection systems. Water-fuel
ratios as high as 0.25:1 were used.
Modern Testing
Testing was carried out in 1997 by Lars Eriksson
of Sweden’s Linkoping University. This testing is important over earlier work
because it used a modern automotive engine, state of the art engine monitoring,
and fuel with an octane rating commensurate with normal automotive fuels. The
engine used was a four cylinder (probably a Saab 2 or 2.3 litre) run with an
air/fuel ratio of 14.7:1, held at 1500 rpm and with 55Nm of torque being
developed.
The water injection volume was unmeasured – a
compressed air spray-gun was simply used to squirt fine water drops on the
throttle butterfly as the engine ran on the engine dyno. This lack of precise
relationship between fuel and water additions is also useful, because it shows
what effects can be gained by even a non-optimal water injection system.
After the water injection started, the peak
cylinder pressure occurred 4 degrees later and output torque decreased slightly.
However, advancing the ignition timing gave about 2 per cent more torque than
was achieved without water injection.
The author states in his conclusion that: ”....the
results give a new method to actively increase engine efficiency by combining
water injection with ionisation current based spark control.” (The author’s
primary research interest was using ionisation current spark plug measurement to
dictate ignition timing, but there’s no reason that other spark advance methods
cannot be used with water injected engines.)
In 1999, R Lanzafame of the University of Catania
conducted tests on a single cylinder CFR (variable compression ratio) engine.
Low octane fuel was used with the water/fuel ratio varied over the range from 0
to 1.5:1. Water was supplied by a high pressure (up to 2 megapascal – 290 psi)
pump through a single nozzle.
Here is some of what the paper says:
Experimental test data show that water
injection into an unheated manifold, when the engine speed is reasonably high,
will not give water a sufficient time to vaporise during the compression stroke.
Of course, in normal operation of a naturally aspirated engine the water does
not vaporise until after combustion is well under way. This effect well explains
why injection of water into very highly compressed or supercharged engines has
been successful.
It is well evident that water injection slows
the combustion process down in SI
[spark ignition]
engines. Thus to maintain
standard MBT
[mean best torque]
spark setting the timing should be
advanced... when using water injection gasoline combinations.
The use of water injection in water/fuel ratios
from 0-1.5:1 caused the research octane number (RON) to rise from 70 to 93 and
the motor octane number (MON) to increase from 64 to 90. NOx emissions were
substantially decreased, being reduced by more than 50 per cent when a
water/fuel ratio of 1.5:1 was employed. Lanzafame suggests that the best results
of water injection come with a water/fuel ratio of 1.25:1.
With an intake air temp of 143 degrees C and a
water/fuel ratio of 1:1, the paper shows that peak cylinder pressure occurred
about 20 crankshaft degrees later and that the peak cylinder pressure was
reduced from 56 Bar to 37 Bar. With water injection occurring, rapid
fluctuations in peak pressure were also much reduced. Exhaust gas temperatures
also dropped, falling from 705 degrees C with no water injection to 692 degrees
C with a water/fuel ratio of 0.5:1, 675 degrees C with a water/fuel ratio of
1:1, and 665 degrees C with a water/fuel ratio of 1.5:1.
Conclusion
The data presented in this story is just a small
sample of the information available from scientific and engineering sources.
There’s absolutely no doubt that water injection, if properly engineered and
integrated with the existing engine management system, can be highly effective.
In fact, to summarise:
-
When water injection is being used without any
other engine ‘tune’ changes simultaneously being made (eg more advanced ignition
timing, increased boost, increased compression ratio), power is likely to
decline.
It’s all food for a lot of thought isn’t it?
Jet
Aircraft
Surprising
at it may be to some, water injection has also been used on jet aircraft.
Aircraft
Gas Turbine Powerplants, published in 1979, shows this water injection
system as typical on early jets and suggests the Boeing 707 used 300 US gallons
(1136 litres) per engine in a 3 minute take-off climb.
The
publication suggests a typical ‘takeoff wet’ increase in thrust of 10-15 per
cent, resulting from the ability to flow more fuel without exceeding maximum
temp limits.
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References
Bureau
of Naval Personnel, (1957), Aviation Machinists’ Mate 3, Navy Training
Courses NAVPER 10338
Chatfield,
S., et al, (1949), The Airplane and its Engine, Fifth Edition,
McGraw-Hill
Eriksson,
L. (1997), Increasing the Efficiency of SI-Engines by Spark-Advance Control
and Water Injection, Report LiTH-R-1939, Linkoping University, Sweden
Lanzafame,
R. (1999), Water Injection Effects in a Single-Cylinder CFR Engine, SAE
Paper 1999-01-0568
Otis,
C. (1979), Aircraft Gas Turbine Powerplants, Aviation Maintenance
Publishers, Wyoming, USA
Majewski,
WA & Khair, MK (2006), Diesel Emissions and Their Control, SAE
International
Ricardo,
H. & Hempson, J. (n.d.), The High-Speed Internal Combustion Engine,
Fifth Edition, Blackie & Sons Ltd
Rothrock,
A, et al, (1942), The Induction of Water to the Inlet Air as a Means of
Internal Cooling in Aircraft-Engine Cylinders, NACA Report No. 756
Vandeman,
J. & Heinicke, O., (1945), Effect of Water-Alcohol Injection and
Maximum-Economy Spark Advance on Knock-Limited Performance and Fuel Economy of a
Large Air-Cooled Cylinder, NACA report E-264, NACA MR No E5H12
Zeilinger,
K. (1971), Influence of Water Injection on Nitric Oxide Formation in Petrol
Engines, in Air Pollution Control in Transport Engines, Institute of
Mechanical Engineers, London
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