Let's assume 1 ft. lb. of torque at a flywheel (no rotation just force) and how the torque changes going through the driveline (ignoring parasitic driveline losses).
1 ft.lb. x (2nd gear ratio) 1.727 x (final drive) 4.062 x (wheel assuming 24.85" diameter) .9654 = 6.77 lb. ft. of torque at the wheel.
In order to calculate power we multiply torque by rpm and divide by 5252 correct?
So at 5000 rpm we have (6.77 ft.lb. of torque x 5000 rpm)/5252 = 6.45 hp
The same example in 1st gear is (12.04 ft. lb. of torque x 5000 rpm) = 11.46 hp
It appears that the greater the torque multiplication by the driveline the greater the hp at the wheels.
Where am I going wrong?
Jim,
So it looks like the confusion is you are multiplying apples with oranges.
Lets take a look back at your exmaple:
At the crank, you are providing 1 lb ft at 5000 rpm. With P=T*w/5252, we get the crank power to be P=0.952 hp.
For the
same example, lets look at the power
at the wheels:
At the wheels, in 2nd gear, 1 lbft --> 6.77 lbft at the wheels. NOW, the confusion is what is the RPM of the
wheels?
Using the same gear ratios provided, the wheels should be spinning at: 5000 rpm/1.727/4.062/0.9654 = only 738 rpm.
So, the Power
at the wheels = Torque
at the wheels *
wheel RPM
In our example, P= (6.77 * 738)/5252 = 0.952 hp!! Just like before when we took crank torque and crank rpm.
So there in-lies the confusion. As shown, the power is said to be conserved from crank to wheels, where the torque is directly related to the gearing. However, since the
speed of the wheel is inversely related to the gearing, power is unaffected by the gearing.
So while more torque gets delivered to the road at lower gears, the wheels are spinning very slow, as such, a dyno pull in a lower gear won't give any power gains.
I hope that helps :redface:.
Lucas
