Impacts of Driving Patterns on Well-to-wheel Performance of Plug-in Hybrid Electric Vehicles

Raykin, Leonid

27 November 2013

The well-to-wheel (WTW) environmental performance of plug-in hybrid electric vehicles (PHEVs) is sensitive to driving patterns, which vary within and across regions. This thesis develops and applies a novel approach for estimating specific regional driving patterns. The approach employs a macroscopic traffic assignment model linked with a vehicle motion model to construct driving cycles, which is done for a wide range of driving patterns. For each driving cycle, the tank-to-wheel energy use of two PHEVs and comparable non-plug-in alternatives is estimated. These estimates are then employed within a WTW analysis to investigate implications of driving patterns on the energy use and greenhouse gas emission of PHEVs, and the WTW performance of PHEVs relative to non-plug-in alternatives for various electricity generation scenarios. The results of the WTW analysis demonstrate that driving patterns and the electricity generation supply interact to substantially impact the WTW performance of PHEVs.

light duty vehicles

plug-in hybrid electric vehicles

life cycle assessment

well-to-wheel

energy

petroleum

greenhouse gas emissions

electricity generation

driving patterns

driving conditions

driving cycles

travel demand modeling

Transportation Tomorrow Survey

Ontario

Greater Toronto Area

Emme

CALMOB6

Autonomie

GREET

0775

Impacts of Driving Patterns on Well-to-wheel Performance of Plug-in Hybrid Electric Vehicles

Raykin, Leonid

27 November 2013

The well-to-wheel (WTW) environmental performance of plug-in hybrid electric vehicles (PHEVs) is sensitive to driving patterns, which vary within and across regions. This thesis develops and applies a novel approach for estimating specific regional driving patterns. The approach employs a macroscopic traffic assignment model linked with a vehicle motion model to construct driving cycles, which is done for a wide range of driving patterns. For each driving cycle, the tank-to-wheel energy use of two PHEVs and comparable non-plug-in alternatives is estimated. These estimates are then employed within a WTW analysis to investigate implications of driving patterns on the energy use and greenhouse gas emission of PHEVs, and the WTW performance of PHEVs relative to non-plug-in alternatives for various electricity generation scenarios. The results of the WTW analysis demonstrate that driving patterns and the electricity generation supply interact to substantially impact the WTW performance of PHEVs.

light duty vehicles

plug-in hybrid electric vehicles

life cycle assessment

well-to-wheel

energy

petroleum

greenhouse gas emissions

electricity generation

driving patterns

driving conditions

driving cycles

travel demand modeling

Transportation Tomorrow Survey

Ontario

Greater Toronto Area

Emme

CALMOB6

Autonomie

GREET

0775