Everything about Higher Heating Value totally explained
The
higher heating value (HHV;also known as the gross calorific value or gross energy) of a
fuel is defined as the amount of
heat released by a specified quantity (initially at 25 °C) once it's
combusted and the products have returned to a temperature of 25 °C.
The higher heating value takes into account the
latent heat of vaporization of
water in the combustion products, and is useful in calculating heating values for fuels where
condensation of the reaction products is practical (for example, in a gas-fired boiler used for space heat).
Measuring heating values
The higher heating value is experimentally determined in a
bomb calorimeter by concealing a
stoichiometric mixture of fuel and oxidizer (for example, two moles of hydrogen and one mole of oxygen) in a steel container at 25 °C. Then the
exothermic reaction is initiated by an ignition device and the combustion reactions completed. When hydrogen and oxygen react during combustion, water vapor emerges. Subsequently, the vessel and its content are cooled down to the original 25 °C and the higher heating value is determined as the heat released between identical initial and final temperatures.
When the
lower heating value (LHV) is determined, cooling is stopped at 150 °C and the reaction heat is only partially recovered. The limit of 150 °C is an arbitrary choice.
Relation to lower heating value
The difference between the two heating values depends on the chemical composition of the fuel. In the case of pure carbon or carbon dioxide, both heating values are almost identical, the difference being the sensible heat content of carbon dioxide between 150 °C and 25 °C (
sensible heat exchange causes a change of temperature. In contrast,
latent heat is added or subtracted for
phase changes at constant temperature. Examples:
heat of vaporization or
heat of fusion). For
hydrogen the difference is much more significant as it includes the sensible heat of water vapor between 150 °C and 100 °C, the latent heat of condensation at 100 °C and the sensible heat of the condensed water between 100 °C and 25 °C. All in all, the higher heating value of hydrogen is 18.2 % above its lower heating value (or the LLV is 15.5% below the HHV) or in absolute numbers, 142 MJ/kg vs. 120 MJ/kg for the two cases. For
hydrocarbons the difference depends on the hydrogen content of the fuel. For
gasoline and
diesel the higher heating value exceeds the lower heating value by about 10 % and 7 %, respectively, for natural gas about 11 %.
Higher (HHV) and lower (LHV) heating values for some fuels are shown in the following table.
Table A.
Heating values for selected fuels
Fuel HHV(MJ/kg)
LHV(MJ/kg) HHV/LHV LHV/HHV
Coal 1) 34.1 33.3 1.024 0.977
CO 10.9 10.9 1.000 1.000
Methane 55.5 50.1 1.108 0.903
Natural gas 2) 42.5 38.1 1.115 0.896
Propane 48.9 45.8 1.068 0.937
Gasoline 3) 46.7 42.5 1.099 0.910
Diesel 3) 45.9 43.0 1.067 0.937
Hydrogen 141.9 120.1 1.182 0.846
1)
Anthracite, average
2)
Groningen (
The Netherlands)
3) Average gas station fuels
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