Lets look at a slug of air and fuel going through and engine...Basically, two forces act on the incoming air/fuel charge: the negative pressure exerted by downward moving piston and the positive force pressure present by atmospheric pressure (14.7 psi @ 60 degrees F). Together these two provide impetus for the inlet charge. If a cylinder is left open to atmospheric pressure (with piston at BDC) a given volume of gas (by weight) would occupy the void. During normal engine operation, another volume of gas by weight, will be "drawn" into this same cylinder. By comparing the two mixture weights just discussed, a number can be found which when presented as a percentage, represents the so called volumetric efficiency of the engine. A value of 100% represents the volumetric efficiency when the volume (by weight) inducted during actual engine operation exactly equals the volume( by weight) that would fill the engine if it were stopped and left open to the atmospheric pressure filling.
Following combustion, the spent gas must be removed from the cylinder before a fresh batch makes its appearance from the intake system. An exhaust valve opens ands the burned mix (still at pressure higher than atmospheric pressure ) exits out the exhaust manifold, through the muffler and out the tail pipe. This is a base line point of reference.
As Brewnog pointed out, it is an accepted fact that increased quantities of fuel and air are a function of increased quantities of engine output.Scavenging or ram effect is a technique to improve volumetric efficiency VE without the use of turbo chargers or super chargers.both mechanical means to force feed the cylinder with more fuel/ air charge. Air is probably the cheapest fuel component available, and since it is a fuel carrying vehicle, the ram trick involves increasing intake air flow. (assume we are using cylinder heads designed for maximum flow as are the intake and exhaust).
RAM or scavenging effect is most efficiently accomplished at a given engine RPM. This is based on the fact that the velocity of pressure waves traveling in intake and exhaust passages is variable with engine speed. Consider what happens during the intake cycle. The piston begins its downward intake stroke from TDC. Its sucking action is the greatest (theoretically) at a point 90 degrees in the crankshaft rotation past TDC. Piston speed is at maximum value at this point.During the action of the piston, a pressure wave in the intake passage is created. This is a negative (rarefraction) wave that does, oddly enough, travel toward the inlet of the intake passage. The departing negative wave actually adds to the speed of the incoming fuel /air charge, increasing cylinder filling by promoting the passage of more mix per unit of time (engine RPM). As engine speed increases, the frequency and number of negative pressure waves increase, altering the ram effect. When a negative wave reaches the intake inlet, it meets atmospheric pressure head on. It reacts in the form of a positive compression wave that travels backwards down the intake passage, helping force more mix into the cylinder.
There is a lot more that goes on and i can comment on this later but I have to close for now..
