Calculating engine starter’s energy use
First, consider the case with negligible auxiliary loads (no air conditioning).
For a Civic-sized engine (1.8 liters), this US DOE worksheet estimates about 0.3 US gallon/hour fuel consumption at idle.
Here is a conservative starter calculation:
- The Civic starter is rated at 1.0 kW (83A$\times$12V). A 3 second start therefore produces 3 kJ. Assume an additional 25% in battery internal dissipation that must be replaced.
- As you note, this energy must be replenished by the ICE (internal combustion engine). Max ICE efficiency is only 30%. The incremental efficiency, which is what matters for this small additional load, is no doubt higher, but I’ll use 25% as a conservative estimate.
Alternator efficiency is not great either; I’ll use a conservative 50%.
With these values, it requires 3.0 kJ$\times$(1.25 / 0.25 / 0.5) = 30 kJ worth of fuel to recharge the battery (Note the overall charging efficiency is only 10%!).
Now, the energy density of gasoline is 120 MJ per US gallon (42.4 MJ/kg), so the amount of fuel required to recharge the battery, including all the inefficiencies, is 30 kJ $\div$ 120 MJ/gal = 0.00025 US gallon.
So, the “crossover” idle time in this case, above which it is more efficient to stop and restart, is 0.00025 gal $\div$ 0.3 gal/hour $\approxeq$ 8.3 $\times10^{-4}$ hours, or about 3 seconds.
Now suppose an air conditioner (PDF) is consuming 1 kW of electrical power.
- With the engine running, the A/C requires (via the alternator) an additional engine fuel consumption equivalent to 1 kW / 0.5 / 0.25 = 8 kW, or 29 MJ/hour, or 0.24 gal/hour of gasoline. For a duration $t$, the total fuel consumption with the engine running is (0.3 + 0.24)$t$ = 0.54$t$ (with $t$ in hours).
- With the engine stopped, the A/C still consumes 1 kW, or 3.6 MJ per hour. With that low 10% charging efficiency, it requires 36 MJ worth of fuel (or 0.3 gal) to recharge an hour’s worth of A/C operation. Adding in the starter contribution, the total fuel requirement is 0.00025 + 0.3$t$ (with $t$ again in hours).
Equating these two new fuel requirements, the crossover time with the A/C on increases, but only to about 4 seconds.
Although the battery charging efficiency is low, the waste of the idling fuel consumption dominates the calculation.
Note that I don’t have a reference for the 25% battery re-charge inefficiency. Unfortunately, that’s an important number when running an A/C, since it reduces the advantage of shutting off the engine. At some high load level (in the neighborhood or 4 kW) that disadvantage outweighs the advantage of turning off the engine.
Further (experimental) data to confirm the above estimates can be found here: http://www.iwilltry.org/b/projects/how-many-seconds-of-idling-is-equivalent-to-starting-your-engine/
In my case it consumes about the same amount of fuel as 7 seconds of idling. However, the additional fuel consumption observed seems almost entirely due to a faster idle speed setting for the first 20 seconds after starting. Any good driver would start moving within 1-2 seconds after starting, which would effectively eliminate the fast idle losses. If you can begin extracting useful work from your engine within 1 second after starting the engine then it appears starting the engine consumes fuel equivalent to about 0.2 seconds of idling.
Firstly, the proof is the the pudding. While I was in Germany I was in a car (a Smart) that automatically turned off the engine when you were stopped and held the brake down, and then re-started the engine when you pushed the gas. It did this so quickly that you didn’t really notice. I assume this is the kind of technology you are referring to. The fact that this is done in a commercial car and apparently improves efficiency shows that, overall, turning off the engine at traffic lights does in fact improve efficiency. For your hard numbers, all you’d need to do is look up the fuel consumption specifications for such a car with and without the engine start/stop feature enabled.
Secondly, with respect to the amount of energy used from the battery by the starter, it’s easy to put an upper bound on the amount of electrical energy used while starting the car using the battery ratings. One of the ratings printed on batteries is the number of cold cranking amps (CCA). This is the amount of current the battery can put out while starting the car at 0 °C. A typical number is 700 CCA for the battery in a four-cylinder. Assuming the starter uses the maximum current, equal to the number of CCA (it doesn’t) and it takes 10 s to start the car (it doesn’t), gives an upper bound of 700 A $\times$ 12 V $\times$ 10 s $=$ 84 kJ of energy use by the starter.
84 kW $\approx$ 112 HP is on the lower end of the maximum power a four-cylinder can put out. 84 kW $\times$ 1 s $=$ 84 kJ, which means that our upper-bound estimate of the energy used by the starter is equivalent to about 1 s of a four-cylinder going full-out. Engines do in fact put out this kind of power in practice; that’s what you get when you’re on the highway in your power band and you floor it, which might be a reasonable thing to do when getting onto the highway in a small car. If you want to know how much idle time this is equivalent to, you’d have to look up the idling fuel consumption, which isn’t really physics and I don’t know off the top of my head.
Finally, all of the energy stored in the battery is less than the battery capacity in amp-hours multiplied by the battery voltage in volts. I say “less than” because the voltage will drop somewhat before the battery goes dead. For a 70 Ah battery at 12 V this is 840 Wh $\approx$ 3 MJ, which is still only equivalent to 30 s of a 100 kW engine.
In general, the batteries we encounter in day-to-day life store a puny amount of energy when compared with fossil fuels. That is why it has been so hard to make a competitive electric car. Tell that to the bloke.
You can find references for the numbers in this post (1) in a vehicle owner’s manual, and (2) printed on a car battery.
On average a 4 or 6 cylinder car will draw about 250 amps for 3 seconds to start. That works out to be 0.21 Amp-Hrs.
The alternator on a car can easily restore that amount of energy in 30 seconds at about 40% efficiency. Which means about 0.52 Amp-Hrs are needed from the alternator to recover the battery.
Most alternators put out about 60 Amp-hrs at idle or 100+ Amp-hrs when running at higher rpm.
Thus starting a car takes about 1% of the the available power coming from the alternator at idle. or about 0.65% when driving. So this shows the actual load on the battery and the alternator are insignificant.
To compare the difference in electrical energy wasted to the fuel wasted in starting a car or idling a car is dramatic. The motor is using a ton of power every second it is running on the order of 100 kwatts. Turning it off even for a second is going to save a dramatic difference in overall power consumption. If you ran the engine for just 1 second you're talking about 2.3 Amp-Hrs (assuming all that power is compared to a 12V battery producing 100 kwatts).
Or if you compare it to 3 seconds of starting that's 6.95 Amp-hrs (engine running for 3 seconds) vs 0.52 Amp-hrs to recharge after starting.
Stopping the car is a no-brainer.
EDIT: Using Art's 0.4 gal/hour at idle for a 2.4L, that is 1,111 A-Hr worth of energy in a 12V system. By comparison that's 11 standard 12 volt automotive batteries worth of power every hour. Now consider you only need about 0.52 A-Hrs to recharge after each start you can see that we are talking about 0.045% of a power drain which equates to about 2 seconds of the engine's fuel consumption at idle, much less if you are driving. (1,111 A-hr = 0.31 A-seconds)
Sources/Estimates:
- 4 cylinder engine hp/watts (I used a low estimate of 100 kwatts or 134 HP.)
- Alternator current vs rpm vs efficiency (see first graph Figure 3.)
- Most small car starters are 1.4KW or ~116 amps or 0.097 Amp-hrs at 3 seconds, I roughly doubled the number to 250 amps to cover just about any type of small engine. For example the popular Honda Civic uses a Denso 280-0324 starter that is only rated at 1.0 kW or 83.3 amps or 0.069 Amp-Hrs for 3 seconds.
- 1 a-hr @ 12V = 43.2KJ, 1 gal = 120MJ => 2.78 kA-Hr @ 12V.