You're kidding, right? The choice Broder had was between driving on a freeway and driving through Manhattan. It was not in any way a choice between stop and go driving and steady-state driving at the same average speed.
Stop-and-go driving decreases the range of an electric vehicle
Compared to steady-state driving at the same average speed, yes. Compared to steady-state driving at a significantly higher average speed, not necessarily.
this is physics 101.
Okay, let's do some physics. The energy required to move a car through a distance D is F * D, where F is the force needed to push the car. For travel at a steady speed, F is given by the following equation:
F = c0 + c1 * v + c2 * v^2
where c0, c1, and c2 are constants that are determined by vehicle and environmental characteristics. (Briefly, c0 is the coefficient of friction between the tires and the road times the weight of the car; c1 is a (usually very small) constant related to the internal friction of rotating parts in the car; c2 is 1/2 rho Cd A, where rho is the air density, Cd is the car's drag coefficient, and A is the car's cross-sectional area. The key is that all of these things can be taken to be constant for the duration of the trip.)
For stop and go driving, F is given by the above formula times a constant e, where e is determined by the efficiency of regen; if e = 1 then regen is 100% efficient and all of the the vehicle's kinetic energy is reclaimed on each decel. If e > 1 then regen only captures a portion of the vehicle's kinetic energy, the portion being 1/e.
So if we compare stop and go driving at an average speed v1 to steady-state driving at an average speed v2, we have
E1 = F1 * D = e (c0 + c1 * v1 + c2 * v1^2) * D
E2 = F2 * D = (c0 + c1 * v2 + c2 * v2^2) * D
If we take v2 = 2 * v1, which is a conservative estimate for Broder's situation (25 mph average speed in the city vs. 50 mph average speed on the freeway), we have
This is going to be positive for any vehicle except a heavy one with a low drag coefficient; practically no vehicles have that. So stop and go driving at 25 mph is going to save energy compared to steady state driving at 50 mph. This is the sort of calculation that I suspect was in the minds of the Tesla people when they told Broder that the stop and go segment in Manhattan was going to give him better range than driving on the freeway.
> Compared to steady-state driving at the same average speed, yes. Compared to steady-state driving at a significantly higher average speed, not necessarily.
Look -- stop trying to change the subject. Obviously if Broder wanted to maximize range and with the choice to either engage in stop-and-go driving or drive at a constant speed with the same average speed, physics says drive at a constant speed. Your claim that one can only drive fast or engage in stop-and-go driving is false. If the point is to maximize the car's range, the driver can drive at any speed he cares to. And Broder did just that -- he drove as slowly as necessary to prevent pointless losses of energy.
Do you really think that the police will arrest you if you drive too slow on the freeway? Tell that to a long-haul trucker.
> Regen typically recaptures about 80 percent of a vehicle's kinetic energy
Quote: "The miraculous thing about regenerative braking is that it may be able to capture as much as half of that wasted energy and put it back to work."
Quote: "Tesla Motors claims an 87% efficiency for powering the electric motor with the energy in the batteries, and the same efficiency in returning motor power to the batteries via regenerative braking. TM also claims an average 80% mechanical efficiency (this goes down as friction increases at very low speeds), including tire loss. So if I have it right, round trip efficiency from taking electricity out of the battery pack to putting it back in, after regen recovery, would theoretically be .87 x .8 x .8 x .87 = 48.4%. But the Roadster uses regenerative braking only on the rear wheels, so if you actually use the brake pedal (instead of coasting with the regenerative braking on) , then the recovery will be far less. The front disc brakes will absorb most (over half) of the kinetic energy when using the brake pedal, because braking action throws more weight to the front of a car."
Your preliminary assumptions are spectacularly wrong. According to the above, the energy recovered in the Model S is about 20% of that required to get the car to its present speed.
> So if we compare stop and go driving at an average speed v1 to steady-state driving at an average speed v2 ...
Learn about science, and don't post again until you do. Science isolates one variable, the topic of study, and keeps everything else the same to the degree that's practical.
Regenerative braking is much less efficient than driving at a steady pace.
I'm not. The subject is whether or not the Tesla people gave Broder good advice. Obviously that depends on what information he gave them and what they based their advice on. You are basically saying that Broder asked them: "I can drive at 25 mph steady state, or do stop and go driving at an average speed of 25 mph; which will give me better range?" If that were indeed the question he had asked Tesla, you are entirely correct that "stop and go" would have been the wrong answer.
But I believe the question Broder actually asked Tesla was more like: "I can drive at 50 mph on the freeway steady state, or do stop and go driving at an average speed of 25 mph; which will give me better range?" If that was the question he asked Tesla, "stop and go" could have been a correct answer. That's my point.
According to the above, the energy recovered in the Model S is about 20% of that required to get the car to its present speed.
The quote you gave referred to the Roadster; as far as I know the Model S uses regen on all four wheels [Edit: probably not--see below]. That would make it 48.4%, not 20%, assuming there are no other differences between the Roadster and the Model S.
If the correct number is 48.4%, that makes e about 2; so my equation would look like this:
E2 - E1 = [- c0 + 2 * c2 * v1^2] * D
I agree this is less likely to be positive; I would have to see detailed numbers for the Tesla Model S to get a better estimate of c0 and c2. The Tesla people who gave Broder the advice presumably had such detailed data, so they would have been able to make a more accurate calculation of estimated range for each alternative.
Science isolates one variable, the topic of study, and keeps everything else the same to the degree that's practical.
Exactly: to the degree that's practical. Broder was not running a controlled scientific experiment; he was running a real-world test of a vehicle.
[Edit: Looking at the Model S specs on the Tesla web site, they do say it's a rear wheel drive vehicle, and there's no mention of separate regen motors for the front wheels. If so, and if the 20% figure for energy recovery is correct, that would make it extremely unlikely that a calculation like the one I've done would give a positive number. If the Tesla people were basing their response on such a calculation, their numbers for regen energy recovery must be significantly higher than 20%, or they were estimating a significantly higher freeway speed than 50 mph, or (most likely) a combination of the two.]
You're kidding, right? The choice Broder had was between driving on a freeway and driving through Manhattan. It was not in any way a choice between stop and go driving and steady-state driving at the same average speed.
Stop-and-go driving decreases the range of an electric vehicle
Compared to steady-state driving at the same average speed, yes. Compared to steady-state driving at a significantly higher average speed, not necessarily.
this is physics 101.
Okay, let's do some physics. The energy required to move a car through a distance D is F * D, where F is the force needed to push the car. For travel at a steady speed, F is given by the following equation:
F = c0 + c1 * v + c2 * v^2
where c0, c1, and c2 are constants that are determined by vehicle and environmental characteristics. (Briefly, c0 is the coefficient of friction between the tires and the road times the weight of the car; c1 is a (usually very small) constant related to the internal friction of rotating parts in the car; c2 is 1/2 rho Cd A, where rho is the air density, Cd is the car's drag coefficient, and A is the car's cross-sectional area. The key is that all of these things can be taken to be constant for the duration of the trip.)
For stop and go driving, F is given by the above formula times a constant e, where e is determined by the efficiency of regen; if e = 1 then regen is 100% efficient and all of the the vehicle's kinetic energy is reclaimed on each decel. If e > 1 then regen only captures a portion of the vehicle's kinetic energy, the portion being 1/e.
So if we compare stop and go driving at an average speed v1 to steady-state driving at an average speed v2, we have
E1 = F1 * D = e (c0 + c1 * v1 + c2 * v1^2) * D
E2 = F2 * D = (c0 + c1 * v2 + c2 * v2^2) * D
If we take v2 = 2 * v1, which is a conservative estimate for Broder's situation (25 mph average speed in the city vs. 50 mph average speed on the freeway), we have
E2 = (c0 + 2 * c1 * v1 + 4 * c2 * v1^2) * D
Now subtract to get the net energy difference:
E2 - E1 = [(1 - e) * c0 + (2 - e) * c1 * v1 + (4 - e) * c2 * v1^2] * D
Regen typically recaptures about 80 percent of a vehicle's kinetic energy, meaning e is about 1.25. So we have
E2 - E1 = [-0.25 * c0 + 0.75 * c1 + v1 + 2.75 * c2 * v1^2] * D
This is going to be positive for any vehicle except a heavy one with a low drag coefficient; practically no vehicles have that. So stop and go driving at 25 mph is going to save energy compared to steady state driving at 50 mph. This is the sort of calculation that I suspect was in the minds of the Tesla people when they told Broder that the stop and go segment in Manhattan was going to give him better range than driving on the freeway.