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DEFINITIONS of terms used in the MOTA manual, and the outputs produced by MOTA.
TRAPPED SWEPT VOLUME.
The total volume above the piston after the exhaust port closes during
compression.
CYLINDER CLEARANCE VOLUME.
Volume above piston when it is at Top Dead Centre ( excluding spark plug hole ).
COMPRESSION RATIO.
Usually taken in a two-stroke engine as the Trapped Swept Volume divided by the
Cylinder Clearance Volume.
SCAVENGING.
The process by which the cylinder is filled with fresh charge and the spent
charge ( or some of it ) is exhausted.
DELIVERY RATIO.
Mass of fresh charge supplied to the cylinder during scavenging divided by the
mass of atmospheric air which would be contained in the swept volume ( not the
trapped swept volume ) of the engine.
SCAVENGE RATIO (mass ).
Mass of fresh charge supplied to the cylinder during scavenging divided by the
mass of atmospheric air which would be contained in the entire cylinder volume (
ie swept volume + clearance volume ). Clearly there is a subtle difference
between Delivery Ratio and Scavenge Ratio (mass), some sources equate them.
SCAVENGE RATIO ( volume ).
Replace “mass” in the definition of the mass based quantity by “volume”.
Clearly, the volume of the delivered air has to be translated to the temperature
and pressure of the cylinder, so this is not an easy quantity to calculate (
MOTA does it )
SCAVENGING EFFICIENCY.
The mass of air delivered to the cylinder which has been trapped ( ie not passed
through from the transfer port to exhaust port during scavenging ), divided by
the total mass of gas in the cylinder when the exhaust port closes. The latter
is composed of fresh charge, burnt gas and fresh charge from the last cycle.
PURITY.
As for scavenging efficiency except that the quantity divided is the total fresh
charge ( ie the amount delivered this cycle plus that left over from the last
cycle.
TRAPPING EFFICIENCY.
The ratio of mass of delivered charge which has been trapped to the total mass
of delivered charge. Remember that some of the latter exits the exhaust port
before combustion starts, ie during scavenging. This turns out to be
approximately equal to the scavenging efficiency divided by the mass based
scavenging ratio.
CHARGING EFFICIENCY.
The mass of fresh charge trapped in the cylinder during scavenging divided by
the mass of atmospheric air which fill the entire cylinder volume when the
piston is at Bottom Dead Centre. It is equal to the Trapping Efficiency times
the mass based Scavenge Ratio ( nearly equal to the Scavenging Efficiency ).
BMEP. ( Brake Mean Effective Pressure )
This quantity, multiplied by the engine's swept volume and number of revolutions
per second, gives the actual power developed by the engine.
PMEP. ( Pumping Mean Effective Pressure )
This quantity, multiplied by the engine's swept volume and number of revolutions
per second, gives the power required to compress the charge in the crankcase and
compress the charge in the cylinder. Aside from friction, work must be done at a
rate greater than this power before the engine produces any useful output.
FMEP. ( Friction Mean Pressure )
This quantity, multiplied by the engine's swept volume and number of revolutions
per second, gives the power required to overcome friction during the engine's
operation. When added to the power required to overcome charge compression, the
result represents the power that the engine needs to develop to do any useful
work.
IMEP. ( Indicated Mean Effective Pressure )
BMEP + PMEP + FMEP, when multiplied by the engine's swept volume and number of
revolutions per second, the result is the total power being developed by the
charge in the engine. Obviously, the total useful power is this quantity minus
that due to the charge compression and friction.
BSFC. ( Brake Specific Fuel Consumption )
This is the fuel consumption in kg/kw-hours. If the engine has a power output of
5kw, a BSFC of 0.5kg/kw-hour, and runs for 10 hours, it will consume 5 x 0.5 x
10 = 25kg of fuel.
DELIVERY AND EXHAUST FLOW RATIOS.
The ratios of gas mass flows to a reference mass flowing through the intake and
exhaust ports of an engine during a revolution. The relevant point is that they
should be within 2 - 3% of each other. If not, there may be a problem with the
simulation.