Think of BMEP it as specific torque- or torque per litre- that's all. It allows you to compare how well an engine produces torque for the capacity, so you can compare submarine engines (say) with ... Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM) Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM) Mean effective pressure (MEP) is defined by the location measurement and method of calculation, some commonly used MEPs are given here. Brake mean effective pressure (BMEP) - Mean effective pressure calculated from measured brake torque.

Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM) Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM)

Think of BMEP it as specific torque- or torque per litre- that's all. It allows you to compare how well an engine produces torque for the capacity, so you can compare submarine engines (say) with ... Consider the fact that, to produce 880 HP at 9000 RPM, requires 513 lb-ft of torque, for a peak-power BMEP of nearly 216 PSI (14.92 bar, torque ratio of 1.43). Peak torque for that same engine was typically about 535 lb-ft at 7800 RPM, for a peak BMEP of over 226 psi (15.6 bar, torque ratio of 1.50). THAT is truly astonishing. Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM) Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM)

Mean effective pressure (MEP) is defined by the location measurement and method of calculation, some commonly used MEPs are given here. Brake mean effective pressure (BMEP) - Mean effective pressure calculated from measured brake torque. Mean effective pressure (MEP) is defined by the location measurement and method of calculation, some commonly used MEPs are given here. Brake mean effective pressure (BMEP) - Mean effective pressure calculated from measured brake torque.

Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM) Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM) Consider the fact that, to produce 880 HP at 9000 RPM, requires 513 lb-ft of torque, for a peak-power BMEP of nearly 216 PSI (14.92 bar, torque ratio of 1.43). Peak torque for that same engine was typically about 535 lb-ft at 7800 RPM, for a peak BMEP of over 226 psi (15.6 bar, torque ratio of 1.50). THAT is truly astonishing.

Mean effective pressure (MEP) is defined by the location measurement and method of calculation, some commonly used MEPs are given here. Brake mean effective pressure (BMEP) - Mean effective pressure calculated from measured brake torque. Mean effective pressure (MEP) is defined by the location measurement and method of calculation, some commonly used MEPs are given here. Brake mean effective pressure (BMEP) - Mean effective pressure calculated from measured brake torque.

Mean effective pressure (MEP) is defined by the location measurement and method of calculation, some commonly used MEPs are given here. Brake mean effective pressure (BMEP) - Mean effective pressure calculated from measured brake torque. Power-Torque Torque (lb.in) = 63,025 x Power (HP) / Speed (RPM) Power (HP) = Torque (lb.in) x Speed (RPM) / 63,025. Torque (N.m) = 9.5488 x Power (kW) / Speed (RPM)