SUV Electric¤

SUV Class Definition¤

The Sport Utility Vehicle (SUV) class is a versatile category encompassing four-wheeled, two-axle vehicles, originally designed for cargo transportation but now primarily used for passenger mobility.

SUV Technology Model¤

The SUV technology model encompasses light trucks, including:

Pickup trucks
Sport utility vehicles (SUVs)
Minivans
Vans
Special purpose vehicles

These are modeled within the context of passenger transportation.

Performance Metrics¹¤

The SUV class is characterized by specific annual performance metrics and usage parameters:

Annual Distance (d_annual): The average distance covered annually by an SUV is 16,462 km.
Average Occupancy Rate (n_lpv): The mean number of passengers per vehicle is calculated to be 1.7.
Utilization Factor: Set at 5%, this reflects an average daily use of 1 hour and 15 minutes per day.
Reference Capacity: Calculated at 63.89 passenger-kilometers per hour (pkm/h), this metric is derived from the formula:

\[ ref_{size} = \dfrac{d_{annual} \cdot n_{lpv}}{8760 \cdot c_p} \]

Where c_p represents the capacity utilization percentage.

Battery Electrical Vehicle¤

A 100% electric vehicle is powered solely by electricity. This electricity is used to supply an inverter with direct current which, using the principle of electromagnetism, converts electricity into mechanical energy and moves the vehicle. As the vehicle is not connected to the electrical grid while on the move, it is necessary to ensure its power supply by other means. To do this, BEVs store electricity in an on-board rechargeable battery.

Among the battery types presented, lithium batteries are the ones found in electric vehicles currently on the market. Lithium batteries offer the ability to store more electricity (i.e., have greater energy density) in a smaller volume than traditional batteries, such as lead-acid and nickel-metal-hydride batteries. Lithium batteries are also lighter than conventional batteries.

ES Model Parameters¤

All the parameters concerning the SUV Electric are listed in the table below.

entry_key	value	unit	sets	source_reference
ELECTRICITY_MV (layer)	-0.298	kWh	NA	Agez, Maxime; Ménard, Jean-François; Saunier, François, (2022): "Analyse du Cycle de Vie de Filières Énergétiques et de Leur Utilisation pour le Transport Routier au Québec – Partie 2 : Utilisation"
MOB_PRIVATE (layer)	1	pkm	NA	Agez, Maxime; Ménard, Jean-François; Saunier, François, (2022): "Analyse du Cycle de Vie de Filières Énergétiques et de Leur Utilisation pour le Transport Routier au Québec – Partie 2 : Utilisation"
c_inv	1614.96	CAD/(pkm/h)	NA	Agez, Maxime; Ménard, Jean-François; Saunier, François, (2022): "Analyse du Cycle de Vie de Filières Énergétiques et de Leur Utilisation pour le Transport Routier au Québec – Partie 2 : Utilisation"
c_maint	13.68	CAD/(pkm/h)/y	NA	Agez, Maxime; Ménard, Jean-François; Saunier, François, (2022): "Analyse du Cycle de Vie de Filières Énergétiques et de Leur Utilisation pour le Transport Routier au Québec – Partie 2 : Utilisation"
lifetime	15	y	NA	Agez, Maxime; Ménard, Jean-François; Saunier, François, (2022): "Analyse du Cycle de Vie de Filières Énergétiques et de Leur Utilisation pour le Transport Routier au Québec – Partie 2 : Utilisation"
ref_size	63.89	pkm/h	NA	Agez, Maxime; Ménard, Jean-François; Saunier, François, (2022): "Analyse du Cycle de Vie de Filières Énergétiques et de Leur Utilisation pour le Transport Routier au Québec – Partie 2 : Utilisation"

References¤

Data Sources
Agez, Maxime; Ménard, Jean-François; Saunier, François. (2022). "Analyse du Cycle de Vie de Filières Énergétiques et de Leur Utilisation pour le Transport Routier au Québec – Partie 2 : Utilisation"

«Canadian Vehicle Survey — 2009 Summary Report» (Ottawa, Canada: Natural Resources Canada, 2009). ↩