But what does this mean?
Simply put, stoichiometric combustion describes the ideal fuel ratio at which the least amount of harmful by-products are produced, mainly in the form of CO2 (a bit more in depth below). With the blend of gasoline more commonly found in our little island and many other countries, this has been derived from the molecular build up of the fuel mix of gasoline and air (bare with it, example to follow).
Now, as many of you may have noticed, when you put juice in the beast, you may have seen on the pump 95 RON (or similar), this describes the octane rating of that particular gasoline blend where RON stands for 'Researched Octane Number'. All octane molecular formations I have seen (bare in mind, I've far from seen them all!!) have a significant carbon (C) and hydrogen (H) content in their make up and it's this carbon content that results in the CO2 production.
The simplest form of octane to carry on with this explanation is isooctane in the form C8H18 (little 8 and 18, and yes, isooctane derived and defined gets a lot more complicated).
Now, many of you may say 'I know how to calculate fuel ratio, it's mass of air/ mass of fuel!' and you'd be right, it is that. But it can be explained in much greater detail with the following equation (here's where the example starts);
Gasoline + x(O2+3.76N2) ---> aCO2 + bH20 + cN2
Where gasoline + x(O2+3.76N2) is the fuel mix and CO2+H2O+N2 is the by-product.
The (O2 + 3.76N2) is derived from the air we breath. Our air is made up of just over 20% oxygen, 78% nitrogen, 1% noble gases and 1% H2O and CO2 - grouping these accordingly, it is said that air is simply 21% oxygen and 79% nitrogen.
Using these values we get the following 0.21 O2/0.21 = 1xO2 (or just O2) and 0.79N2/0.21 = 3.76N2 (explaining the amount of air to nitrogen) and therefore (O2+3.76N2) where x just determines the amount of air required (hope that clears up any questions about that part you were thinking of?!).
Before we delve into solving the equation, I will firstly list some molecular weights (to the nearest whole number for simplicity);
C = 12 g/mole
O = 16 g/mole (therefore, O2 = 32g/mole)
H = 1 g/mole
N = 14 g/mole (therefore N2 = 28 g/mole)
Now we have all the tools we need to complete the job in 2 steps;
Step 1: Solve above equation.
Hopefully, you'll save me another thousand words by just accepting the following method of determination rather than me explaining each time about individual chemical reactions during combustion;
So; Isooctane + x(O2+3.76N2) ---> aCO2 + bH20 + cN2
Therefore; C8H18 + x(O2+3.76N2) ---> aCO2 + bH20 + cN2
Where a = C, b = H/2, x = (2a+b)/2 and c = x(3.76N2), however, as nitrogen appears to be of little concern as out air is mainly made up of the stuff, we'll forget about it as a by-product from this stage on!
Using the conditions above, we now have;
C8H18+ 12.5(O2+3.76N2) ----> 8CO2 + 9H2O (+ 47N2 if you're really interested!?)
Now we have the ideal blend of gasoline and air mix for stoichiometric combustion (or as close as best as possible for this gasoline).
Step 2: Fuel Ratio
Like I said earlier, someone who says fuel ratio is calculated by mass of air/ mass of fuel would be correct and the principle remains the same for this except we're looking at molecular weight to determine the true potential fuel ratio of your blend. For this, we refer back to the molecular weights I listed earlier (and we can now forget about the by-product).
So mass of air takes the form 12.5(O2+3.76N2) as it is the amount of air required for gasoline to be stoichiometric and the isooctane takes the form C8H18 to determine the weight (simply put, 8xC + 18xH), putting this into numerical format we have:
12.5((32)+3.76(28)) / (8*12)+(18*1)
This is equal to:
12.5(137.28) / 114
Which has the final form:
1716 / 114
Which gives a final fuel ratio of 15.05:1 for Isooctane!
So there we have it, fuel ratios and how to determine them explained. Hopefully, what you'll see form this is that you have very little control over fuel ratios (bar buying some octane booster crap) and that your fuel ratio will vary considerably dependent on the blend of gasoline put into your tank.
If you're interested, from the original formula listed above, you can gain so much more valuable information about your fuel and it's potential to be ideal or an absolute nightmare, for example, the air mix can be used to determine the amount of port space taken up by the fuel (meaning less air in ports), as well as NET heat energy releases and calorific values etc.
Interestingly (for me at least), I have come to the conclusion that the mass of fuel must always be 6.8% the mass of air to achieve 14.7:1 (simply derived from (1/14.7)*100=6.
and that there appears to be the very thing a majority of fuels achieve, isooctane for example has a value of 6.6% which is very near but not 6.8% (plus it produces quite a bit of CO2, even at 6.6%).Hope some of you boffins now have a better understanding of fuel ratio and what it is telling you?!
Please, by all means correct me if anything appears inaccurate but I am fairly confident all appears justifiable and correct.
NEEEEEXXXT......
