Here is an example of the 0-100mph acceleration curve that is one of the outputs:-
The full program predicts speeds around a racetrack. Race track data is derived from data-logger information from my track car. The original purpose of the program was for driver training purposes and as a tool for performance-benefit analysis to be conducted for future modifcations to the vehicle.
The summary of the acceleration calculations is as follows:-
At 1 mph increments across the speed range 0 to 250mph I have calculated acceleration in the following way:-
1. Convert miles per hour to metres/second
2. Determine Engine Speed, rpm, in each gear for the speed calculated in step 1.
3. Calculate the Driving Force at the wheels, using the engine’s output curve, gear ratio, final drive ratio and rolling diameter. Note, I add an additional calculation to take into account the effect of the driver’s ability to slip the clutch. I only apply this in 1st gear.
4. Select the appropriate gear: -i.e. if engine rpm in gear”X” > “Upshift rpm” use gear”X+1”, etc
5. Determine maximum driving force at the wheels using the figure from step 3 that corresponds to the gear chosen in step 4. Multiply this by the “transmission efficiency coefficient” to obtain the driving force available at the driven tyres.
6. Determine the maximum accelerative force that can be transmitted by the front and rear wheels (separately) using static mass distribution, downforce generation, and the maximum load transfer due to CG height, wheelbase length, mass and tyre grip coefficient. Since the tyre’s grip coefficient is dependant on the vertical load placed on it you’ll need to iterate this step a couple of times at least. Apply a “grip factor” to the result of the above based on the road bumpiness and the suspension’s compliancy and damping.
7. Find the maximum accelerative force that can be transmitted by the car, based on step 7, where:- RWD = Rear grip only, FWD = Front grip only, 4WD = Front and rear grip.
8. Find the actual maximum driving force which is the lower value of step 5 or step 7.
9. Determine the Total Resistive Forces, where Total resistance = Air drag + Rolling resistance + Gradient “resistance”
10. Determine the acceleration at the chosen road speed using the accelerative force, total resistive force, the car’s mass and the inertia of the car’s rotating parts.
11. Determine the time taken to accelerate from the last mph to this mph using the result of step 10. If there has been a gear change between the last mph and this one, add in the time required to change gear.
12. Determine the distance covered whilst accelerating from the last mph to this mph based on the average speed and the time calculated in step 11.
The above calculations are performed at all speeds from 0 -250 mph. Time taken to accelerate between any two speeds can be determined by summing all the individual times from one mph to the next, and the distance travelled in the same way.
The force data can be assembled into a graph, which shows the total resistive forces (Dark Blue), Maximum force that can be transmitted by the driven wheels (Light Blue), and the accelerative forces available in each gear (green). The top speed of the vehicle is determined when there is no difference in the green and dark blue lines (i.e. where they cross).
The graph below is for an F1 type car with a theoretical constant torque engine between 1000 and 12000rpm, with peak power of 600bhp and 7 roughly equally spaced gears.
The next graph is for the same car model, but fitted with a theoretical constant power engine making 600bhp at all engine speeds from 0 to 12000rpm, and only one gear with the same ratio as gear 7 in the example above.
The third graph shows the two graphs above superimposed showing that the accelerative force of the constant power engine joins all the points equivalent to 600bhp of the constant torque engine/7 gear example.
(In reality it is unlikely that the 2013 engine will be constant torque or constant power)
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You don't have to drive everywhere at full throttle you know?!