The quantity of dissolved carbon dioxide is an important quality attribute of beer. A satisfactory level of carbonation (bottom-fermented beer 0.40–0.60 % w/w, top-fermented beer 0.40–0.80 % w/w) contributes significantly to the perceived freshness and drinkability of beer.
This method is based on the Henry-Dalton law, according to which at a given temperature, the concentration of an ideal gas dissolved in a liquid is proportional to the partial pressure of the gas in the gas phase, given that equilibrium exists. This steady state is reached by forcefully shaking the beer. A manometer is used to measure the total pressure.
Aside from carbon dioxide, there is always a certain amount of air present in the neck of bottled beer as well, causing the partial pressure of the carbon dioxide to shift. Therefore, in order to obtain accurate results, besides the total pressure, the “quantity of air” in the beer must be measured, i.e., the values measured for carbon dioxide, due to the analysis principle, are always too high. For precise measurements of the CO2 content, the partial pressures of the foreign gases (e.g., O2, N2) must be taken into consideration.
The result is determined according to the so-called Haffmans equation:
Determination of the concentration of dissolved carbon dioxide in carbonated beverages by means of volumetric expansion
This analysis is suitable for determining the concentration of dissolved carbon dioxide in carbonated beverages by means of volumetric expansion at concentrations between 2.5 and 6.2 g/l.
This device makes use of a method patented and entitled by Anton Paar "Multiple Volume Expansion". Here, the volume in the measuring chamber is increased in two separate steps, and at the end of each step the equilibrium pressure and temperature are recorded for use in the calculation. The true carbon dioxide content is determined independently of any other gases which may be dissolved in the beverage [1, 2, 3].
The figure below depicts the calibration correcting for air in the sample and shows how the effect of any dissolved gases other than CO2 (air or nitrogen) on the result of the analysis is eliminated using the volumetric expansion employed in this method. The CO2 content is determined after two separate volumetric expansions in the measuring chamber. If no dissolved other gases are present in the sample, the two results are identical, and no correction is necessary. If gases other than CO2 are dissolved in the sample, this causes the result to be lower after the larger volumetric expansion (the second measurement) than the result at smaller volumetric expansion (the first measurement). A correction value is calculated based upon the difference between the two results, which completely eliminates the influence of the dissolved foreign gases (air or nitrogen) on the ultimate result of the analysis.