Definition combustion and components of combustion
Combustion
Oxidation of fuel with oxygen —> Output: Energy in the form of heat
Components
Oxygen
Combustible components (Carbon, Hydrogen, Sulphur)
Non-combustible components (Nitrogen, Chlorine, Ash, Heavy metals, Water)
Combustion equations
3 equations —> all exotherm (get energy out of it)
Carbon + Oxygen —> CO2
Hydrogen + Oxygen —> H2O
Sulphur + Oxygen —> SO2 (Sulfur dioxide)
Types of combustion
Complete
—> Each fuel particle is oxidized
Overstoichiometric: More oxygen than the fuel needs
Incomplete
—> Not every fuel particle gets an oxygen particle
Substoichiometric: Less oxygen than the fuel requires —> Always incomplete combustion
Stoichiometric: Exactly as much oxygen as the fuel requires —> Usually incomplete combustion
Air requirement and air ratio
High nitrogen in the air is only heated during combustion
High fraction of losses in the flue gas
High air ratio —> high losses, higher temp. (danger of formation of NOx)
—> Target: Small lambda (1) BUT: Risk of incomplete combustion (fomation of CO)
Combustion process
Dry fuel is heated up (1—>2)
CmHn = other hydrocarbons
Adiabatic combustion
Heat generation losses
Most important losses —> Exhaust gas losses
Higher exhaust gas mass flow —> Higher air ratio
Calculation of boiler efficiency
Determing factors for the boiler efficiency
Exhaust gas losses determine the efficiency of a heat generator
Parameters
Air ratio / excess air
Return temp. (of the heated water)
Fuel humidity
Actions to optimize combustion
Last changed6 months ago
