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Dyno Tuning
Requirements Before a Dyno Run
Frequently Asked Questions
Theory of Dynamometer Operations
The following is from Dynojet's WinPEP7
software:
Our Dynojet inertia dynamometer is a measuring device for
recording and displaying power and torque of an engine. Its method of
measurement is a direct implementation of the definitions of power and torque.
Correction factors assist in the comparison of these measurements under various
test conditions, making computer hardware and software necessary to obtain,
interpret, and display the data.
Power
Power
in mechanical terms is the ability to accomplish a specified amount of work in a
given amount of time. By definition, one horsepower is equal to applying a 550
pound force through a distance of 1 foot in one second. In real terms, it would
take 1 HP to raise a 550 pound weight up 1 foot in 1 second. So to measure
horsepower, weneed to know force (in pounds) and velocity (in feet per second).
Dynojet’s inertia dynamometer measures power according to the terms just
described. It measures velocity by measuring the time it takes to rotate a heavy
steel drum one turn. The dyno measures force at the surface of the drum by
indirectly measuring its acceleration. Acceleration is simply the difference in
velocity at the surface of the drum from one revolution to the next. The force
applied to the drum is calculated from acceleration using Newton’s 2nd law, (F)orce
= (M)ass x (A)cceleration.
Power
is coupled to the drum by friction developed between the driving tire of the
vehicle and the knurled steel surface on the drum of the dynamometer.
Torque
When
an object rotates around a point, its speed of rotation depends on both an
applied force and the moment arm. The moment arm is the distance from the point
of rotation to where the force is being applied. Torque is the product of the
force and the moment arm. For example, if a rope, wrapped around a drum of 1
foot radius, is pulled with 550 pounds of force, the resulting force is 550
foot-pounds.
The
Torque on the dyno’s drum can be calculated by multiplying the force applied by
the drum’s radius. However, engine torque is not equal to drum torque because
the gearing through the drive train changes the moment arm. The change in the
moment arm is proportional to the ratio of engine speed to drum speed.
Therefore, tachometer readings are necessary to calculate and display engine
torque.
Correction Factor
The
calculation of horsepower or the accuracy of our dynamometer is not dependent on
the location or conditions during the measurement. The performance of the
internal combustion engine is, however, sensitive to atmospheric conditions,
especially air density and air temperature. To compare power measurements taken
at different times or places, it is necessary to compensate for differing
atmospheric conditions.
Correction Factors are used to compensate engine horsepower measurements for
differences in operating conditions during engine testing. The typical
correction factor (CF) is calculated based on the absolute barometric pressure,
air temperature and water content of the air used for combustion by the engine
under test. It attempts to predict the horsepower that would be developed if the
engine were tested at sea level under standard pressure and temperature
conditions.
Absolute barometric pressure is a measure of how hard the air molecules are
being pushed closer to oneanother. The unit of measurement is typically inches
of mercury (inches Hg). The more pressure, the more molecules there are in a
liter of air and the more air the engine gobbles up during the intake stroke.
Absolute barometric pressure is equal to Relative barometric pressure only at
sea level. Relative barometric pressure is reported at airports and by weather
barometers. A good approximation for converting relative barometric pressure to
absolute barometric pressure is:
AbsHg
= RelHg - (Elev/1000)
Where:
AbsHg = Absolute barometric pressure
RelHg = Relative barometric pressure
Elev = test location elevation in feet above sea levelWater content is
calculated from the ambient wet and dry bulb temperatures. Dry bulb temperature
is normal room temperature. Wet bulb temperature is always less than or equal to
dry bulb temperature. As air is blown over the wet bulb thermometer the water
evaporates and cools the thermometer. The dryer the air, the cooler the wet
thermometer indicates. If the ambient air is saturated (humidity = 100%), very
little water evaporates and the wet bulb temperature is equal to the dry bulb
temperature. These measurements are then converted to partial pressure in inches
of mercury and used in the correction formula. Water vapor displaces oxygen and
reduces the amount of combustion air ingested during the intake stroke.
Air
temperature is the temperature of the air entering the intake system of the
engine under test. In some cases this is ambient air temperature, but in other
cases the intake air is significantly heated by the engine and is different than
ambient air. Heat tends to spread air molecules apart. So as temperature
increases, there areless molecules in a liter of air and less air is swallowed
during the intake stroke.
Dynojet’s WinPEP (Performance Evaluation Program for Windows 95) software uses
the SAE’s latest correction formula (June 1990). This formula assumes a
mechanical efficiency of 85% and is much more accurate than earlier formulas at
extreme conditions.
The formula used is:
CF= 1.18 x (29.22/Bdo) x To+460 /
537) - 0.18
Where:
Bdo = Dry ambient
absolute barometric pressure
To = Intake air
temperature in degrees F
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