First, a bit of history to explain the methodology. In the early days of engine balancing, exhaust temperatures were one of the few aspects of the combustion process that were measurable, so technicians attempted to add or subtract fuel to the individual cylinders such that the exhaust temperatures were equalized. While crude by today’s standards, it was easily measurable and typically relatable to the load of the cylinder. This method is still used on some locations today.

Then came Peak Firing Pressure (PFP) Measurement. This method employs a pressure gauge, much like those used in measuring the compression of an auto engine, that is connected to each individual cylinder and captures the Peak Firing Pressure of the cylinders. The gauge is typically screwed onto a cylinder valve attachment (Kiene Valve), the valve is opened, and the pressure gauge is exposed to several firing cycles (usually 8 to 10). The gauge captures the maximum pressure that it read. That value is documented as the peak pressure for that cylinder and the process is repeated for all the other cylinders. Once the values have been collected for the entire engine, a mean value is calculated and the fuel pressure to each cylinder is modified so that the new peak pressure of each cylinder approaches the mean of the engine. This typically requires many iterations, but that’s how it was done.

Historically, we used the parameters we could measure in the field, but today’s equipment allows us the luxury of many more data points. For PFP balancing, the relationship of cylinder pressure to Top Dead Center (TDC), while useful in diagnostics, is not used in the peak pressure mean calculation, but we can measure it if we choose to. What we find is that at or about TDC, the cylinder pressure, that has been increasing steadily since the exhaust port closed reaches a peak, called the Peak Compression Pressure (Cp). In most slow speed engines, this value will vary from cylinder to cylinder, usually due to unequal airing of the cylinders. This is caused by the individual cylinders’ location, as it relates to the air inlet from the turbocharger or piston scavengers, and the pressure pulses generated by the other power pistons as they allow this air to enter during their individual cycles. There may also be differences in the piston and heads on some of these legacy engines causing differences in Cp’s.

In the combustion world, we ideally want to equalize the Equivalence Ratio. While Air-Fuel Ratio is more frequently used in layman’s terms it is not the same as Equivalence Ratio. Air-Fuel Ratio, or lambda (λ), is a measurement of the mixture as compared to stoichiometric while Equivalence Ratio, or phi (Φ), is the ratio of fuel mass flow rate to air mass flow rate. Further, equalizing the phi’s will result in significantly lower Coefficient of Variations (COV’s) in the engine’s performance. 

The cylinder with the lower Cp will not have the same mass or quantity of trapped air as the cylinder with the higher Cp. The two cylinders will therefore require different quantities of fuel to reach an equal phi. The only measurable value to assess the trapped volume of air is the Cp. We know the Cp and we assume the volume is constant between the cylinders, then we can calculate the Peak Pressure Ratio (PPR) as:

PPR = PFP ÷ Cp

Multiplying the Average Engine PPR by the Individual Cylinder Cp’s generates the Target PFP for each cylinder, which is the value to balance to.