9.1 Stoichiometry of Combustion Reactions

Combustion reactions are fundamental to chemical processes, involving fuels reacting with oxygen to produce carbon dioxide and water. Understanding balanced equations and air requirements is crucial for efficient combustion and minimizing environmental impact.

Mass and energy balances in combustion help engineers optimize fuel usage and predict product compositions. These principles are essential for designing effective combustion systems and calculating important parameters like adiabatic flame temperature and combustion efficiency.

Combustion Reaction Fundamentals

Balanced equations for combustion reactions

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• General combustion reaction format depicts fuel reacting with oxygen to produce carbon dioxide and water (hydrocarbon + O₂ → CO₂ + H₂O)
• Balancing combustion equations involves counting atoms on each side and adjusting coefficients to ensure equal numbers
• Hydrocarbon combustion follows formula $C_nH_m + (n + m/4)O_2 → nCO_2 + (m/2)H_2O$ (methane: $CH_4 + 2O_2 → CO_2 + 2H_2O$)
• Alcohol combustion adheres to $C_nH_{2n+1}OH + (3n/2)O_2 → nCO_2 + (n+1)H_2O$ (ethanol: $C_2H_5OH + 3O_2 → 2CO_2 + 3H_2O$)

Air requirements for complete combustion

• Air composition consists of 21% oxygen and 79% nitrogen by volume
• Stoichiometric air-fuel ratio represents minimum air needed for complete combustion
• Calculation steps:
  1. Determine moles of oxygen required from balanced equation
  2. Convert moles of oxygen to moles of air
  3. Apply ideal gas law to calculate air volume if necessary
• Excess air exceeds stoichiometric amount expressed as percentage above requirement

Combustion Products and Balances

Products of fuel combustion

• Complete combustion yields carbon dioxide, water, and nitrogen from air if applicable
• Calculation steps:
  1. Use balanced equation to determine molar ratios
  2. Calculate moles of each product based on fuel input
  3. Convert moles to mass or volume as needed
• Product composition expressed as mole fractions, mass fractions, or volume fractions for gases

Mass and energy balances in combustion

• Mass balance applies conservation of mass principle (fuel + air mass = product mass)
• Energy balance follows first law of thermodynamics $Q - W = ΔH$
• Heating value of fuels measured as Higher Heating Value (HHV) or Lower Heating Value (LHV)
• Adiabatic flame temperature represents maximum temperature in complete combustion calculated using energy balance
• Combustion efficiency measures ratio of actual energy released to theoretical energy content
• Enthalpy of formation used to calculate heat of reaction
• Sensible heat changes temperature without phase change while latent heat causes phase change at constant temperature