Electric Power Generation Needed for Decarbonizing the Transport Sector in the US

Question 4: Power Needed for Decarbonizing the Transport Sector In this question the goal is to quantify how much additional electric power will be needed in the US to replace (a) all gasoline-powered cars and light trucks with battery electric vehicles (EVs), and (b) all diesel-powered heavy trucks with hydrogen-powered fuel-cell vehicles. How can we calculate the total amount of new electric power generation required for this transition?

To calculate the total amount of new electric power generation required to replace gasoline-powered cars and light trucks with battery electric vehicles (EVs), we need to consider several factors. For gasoline engines, assuming an efficiency of 30%, only 30% of the fuel energy is converted into mechanical energy. Out of this baseline mechanical energy, 90% needs to be supplied by electric motors in EVs. Therefore, the effective energy conversion efficiency from fuel to electric power is 30% * 90% = 27%. Assuming a round trip efficiency for battery charging of 90%, and DC motors with 95% efficiency, the overall efficiency from fuel to useful electric power for EVs is 27% * 90% * 95% = 23.29%. To calculate the electric power needed, we can divide the total energy consumption of gasoline vehicles by the overall efficiency: Electric power = Gasoline sales (in gallons) * fuel energy density * overall efficiency = 140 billion gallons * 740 g/L * 44 kJ/g * 23.29% ≈ 1.678 × 10^14 kJ Converting this energy to terawatt-hours (TWh): Electric power (TWh) = 1.678 × 10^14 kJ / (3.6 × 10^6 kJ/TWh) ≈ 46.61 TWh Therefore, approximately 46.61 TWh of additional electric power generation would be needed to replace the gasoline vehicle fleet completely with EVs. For diesel-powered heavy trucks, assuming an efficiency of 40% in converting fuel energy to mechanical energy, the effective energy conversion efficiency for H2 fuel cell-powered trucks would be 40% * 25% * 95% = 9.5%. Following the same calculation as in part (a), using diesel fuel sales for on-road engines (40 billion gallons) and the appropriate energy density, we can estimate the electric power needed to replace the diesel truck fleet with H2 fuel cell-powered trucks. Electric power (TWh) = Diesel fuel sales (in gallons) * fuel energy density * overall efficiency = 40 billion gallons * 840 g/L * 44 kJ/g * 9.5% ≈ 1.343 × 10^13 kJ Converting this energy to terawatt-hours (TWh): Electric power (TWh) = 1.343 × 10^13 kJ / (3.6 × 10^6 kJ/TWh) ≈ 3.73 TWh Therefore, approximately 3.73 TWh of additional electric power generation would be needed to replace the diesel truck fleet with H2 fuel cell-powered trucks.

Calculating Electric Power for EV Transition

Gasoline Vehicles: To determine the electric power needed to replace gasoline-powered cars and light trucks with battery electric vehicles (EVs), we start by considering the efficiency of gasoline engines and the energy conversion processes involved in transitioning to electric power. Gasoline engines have an efficiency of 30% in converting fuel energy to mechanical energy. However, since EVs require electric motors to replace this mechanical energy, we need to account for the efficiency of the electric motors as well. In this case, 90% of the mechanical energy must be supplied by electric motors, resulting in an effective energy conversion efficiency of 27%. Calculation: Electric power = Gasoline sales * fuel energy density * overall efficiency Electric power = 140 billion gallons * 740 g/L * 44 kJ/g * 23.29% ≈ 1.678 × 10^14 kJ Converting the energy to terawatt-hours (TWh) gives: Electric power (TWh) = 1.678 × 10^14 kJ / (3.6 × 10^6 kJ/TWh) ≈ 46.61 TWh This calculation shows that approximately 46.61 TWh of additional electric power generation would be required to replace the gasoline vehicle fleet with EVs.

Calculating Electric Power for H2 Fuel Cell-Powered Trucks

Diesel Trucks: When assessing the electric power needed to replace diesel-powered heavy trucks with hydrogen-powered fuel-cell vehicles, we need to consider the efficiency of diesel engines and the energy conversion efficiency of the proposed replacement technology. Diesel engines have an efficiency of 40% in converting fuel energy to mechanical energy. For H2 fuel cell-powered trucks, the energy conversion involves processes like electrolyzing water to produce hydrogen gas, compressing the hydrogen for storage, and using H2-powered fuel cells to generate electricity. The overall efficiency in this case is 9.5%. Calculation: Electric power = Diesel fuel sales * fuel energy density * overall efficiency Electric power = 40 billion gallons * 840 g/L * 44 kJ/g * 9.5% ≈ 1.343 × 10^13 kJ Converting the energy to terawatt-hours (TWh) gives: Electric power (TWh) = 1.343 × 10^13 kJ / (3.6 × 10^6 kJ/TWh) ≈ 3.73 TWh Approximately 3.73 TWh of additional electric power generation would be needed to replace the diesel truck fleet with H2 fuel cell-powered trucks. These calculations help quantify the electric power requirements for decarbonizing the transport sector in the US and transitioning to cleaner energy alternatives.
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