Considering an Electrified Vehicle? Understand Types of EVs Before Purchasing

Summary

• Switching to an electrified vehicle promises sustainability and better fuel economy, though the variety of options can be daunting
• The electrification of the automotive industry is accompanied by acronyms and concepts that can be confusing
• Understanding the levels of electrification in vehicles is crucial if you’re considering switching to electric transportation.
• The range of electrified vehicles offers distinct benefits and drawbacks related to fuel efficiency, emissions, and driving range

Switching to electric vehicles is an exciting step towards sustainability and improving fuel economy, yet it can be overwhelming due to numerous options. Different levels of electrification, from mild hybrid electric vehicles (MHEVs) all the way up to full-battery electric vehicles (BEVs), have varied benefits and disadvantages. Understanding these differences is crucial for choosing an option that best suits your driving habits, lifestyle, and environmental goals.

This article will guide you through the main characteristics of each electrified powertrain to help you confidently make sense of the array of these modern vehicles. Whether you are in the market for a new or used car and want to prioritize fuel consumption, reduced emissions, or just want the thrill of an EV drive, we dissect their architectures so you can make an educated decision.

Cutting Through the Clutter

Understanding electric vehicle acronyms and concepts is essential for making an informed decision, especially as emissions regulations tighten and major carmakers’ electric goals advance. Navigating the marketing and regulatory jargon is also important for grasping the practical implications of electrified vehicle architectures. 

These range from 48-volt mild hybrids (MHEV) and hybrid electric vehicles (HEV) to plug-in hybrids (PHEV), extended-range electric vehicles (EREV), and pure battery electric vehicles (BEV). Lastly, fuel cell electric vehicles (FCEV) use hydrogen to generate electricity.

Choosing the right type involves evaluating how each architecture fits your needs against evolving emission standards, market acceptance, and the total cost of ownership, which includes purchase price, mileage, maintenance, and local fuel and electricity costs.

Self-Charging Hybrid Electric Vehicles (HEV)

Self-charging hybrid electric vehicles, commonly referred to as traditional hybrids, offer the convenience of a gasoline engine with the added efficiency of an electric motor. Unlike plug-in hybrids (PHEVs), HEVs do not require external charging. Instead, they rely on regenerative braking and the internal combustion engine (ICE) to recharge their batteries.

Key Features of HEVs:

• Dual Power Sources: HEVs seamlessly switch between electric and gasoline power, optimizing fuel efficiency and reducing emissions.
• Electric-Only Mode: HEVs can operate in electric-only mode at low speeds, making them ideal for city driving with zero emissions and silent operation.
• Regenerative Braking: HEVs capture energy during braking, converting it into electricity to recharge the battery, improving overall efficiency.
• Start-Stop Technology: The engine shuts off at stops and restarts when needed, reducing fuel consumption and emissions during idling.

Typical System Specs:

• Battery Voltage: Around 200-300 volts
• Battery Capacity: 1.0 to 2.0 kWh
• Electric Motor Power: 30 to 80 kW (40 to 107 hp)
• Torque: 150-300 Nm (111-221 lb-ft)
• Fuel Efficiency Improvement: 20-50% better than non-hybrid vehicles
• Electric-Only Range: Limited, typically a few kilometers

HEVs are ideal for drivers who want improved fuel efficiency and reduced emissions without charging. They excel in urban environments where stop-and-go traffic allows them to maximize their electric capabilities.

Mild Hybrid Electric Vehicles (MHEV)

Mild Hybrid Electric Vehicles (MHEVs), or 48-volt hybrids, represent a more straightforward and more cost-effective form of electrification. Unlike full hybrids, MHEVs cannot run solely on electric power. Instead, they use an electric motor to assist the internal combustion engine, enhancing performance, improving fuel efficiency, and reducing emissions.

Key Features of MHEVs:

• Electric Motor Assist: The electric motor provides additional torque during acceleration, enhancing responsiveness and overall performance.
• Start-Stop Functionality: The engine shuts off when the vehicle is stationary, reducing fuel consumption and emissions and restarts quickly when needed.
• Regenerative Braking: MHEVs capture energy during braking and store it in a small battery to assist the engine later.
• Smaller Battery and Electric Motor: MHEVs have smaller, lighter batteries and motors, making them more affordable than full hybrids or electric vehicles.

Typical System Specs:

• Battery Voltage: 48 volts
• Battery Capacity: 0.5 to 1.0 kWh
• Electric Motor Power: 10 to 20 kW (13 to 27 hp)
• Torque: 50-150 Nm (37-111 lb-ft)
• Fuel Efficiency Improvement: 10-15% better than non-hybrid vehicles

MHEVs are an attractive option for drivers looking for a modest improvement in fuel efficiency and emissions reduction without the complexity or cost of full hybrids.

Plug-In Hybrid Electric Vehicles (PHEV)

Plug-in Hybrid Electric Vehicles (PHEVs) offer the best of both worlds by combining the benefits of a traditional internal combustion engine with a larger electric battery that can be recharged from an external power source. This allows PHEVs to run on electric power alone for longer distances.

Key Features of PHEVs:

• Extended Electric-Only Range: PHEVs can travel longer distances on electric power alone, which is ideal for daily commutes or short trips without gasoline.
• Dual Power Sources: PHEVs can operate in electric-only, gasoline-only, or combined modes, allowing drivers to optimize their driving experience.
• External Charging Capability: PHEVs can be recharged at home or public charging stations, reducing reliance on the internal combustion engine.
• Regenerative Braking: PHEVs capture energy during braking to recharge the battery, improving efficiency.

Typical System Specs:

• Battery Voltage: 300-400 volts
• Battery Capacity: 8 to 18 kWh
• Electric Motor Power: 50 to 100 kW (67 to 134 hp)
• Torque: 200-400 Nm (148-295 lb-ft)
• Electric-Only Range: 20 to 50 miles (32 to 80 km)
• Fuel Efficiency Improvement: Significantly better than non-hybrid vehicles

PHEVs are ideal for drivers who want the flexibility of electric driving for short trips and the assurance of a gasoline engine for longer journeys. They offer a balanced approach to reducing emissions while maintaining long-range capability.

Extended-Range Electric Vehicles (EREV)

Extended-range electric Vehicles (EREVs) are a type of plug-in hybrid that primarily operates as a battery electric vehicle (BEV) but includes a small internal combustion engine (ICE) that acts as a generator to extend the vehicle’s range. Unlike traditional hybrids, the ICE in an EREV doesn’t drive the wheels but generates electricity to power the electric motor when the battery is depleted.

Key Features of EREVs:

• Primary Electric Operation: EREVs are designed to run mainly on electric power, providing zero tailpipe emissions and instant torque for daily driving.
• Range-Extending Generator: The ICE acts as a generator to extend the range when the battery’s charge is low, eliminating range anxiety.
• Regenerative Braking: EREVs use regenerative braking to capture energy during deceleration, recharging the battery.
• Flexible Driving Modes: EREVs can switch between pure electric and range-extending modes, optimizing efficiency based on driving conditions.

Typical System Specs:

• Battery Voltage: 300-400 volts
• Battery Capacity: 10 to 20 kWh
• Electric Motor Power: 100 to 150 kW (134 to 201 hp)
• Torque: 300-400 Nm (221-295 lb-ft)
• Electric-Only Range: 25 to 50 miles (40 to 80 km)
• Total Range: Over 300 miles (480 km) with the range extender
• Fuel Efficiency: Very high in electric mode

EREVs are ideal for drivers who want the benefits of an electric vehicle with the reassurance of a gasoline-powered backup. They are suitable for daily commutes and longer trips without worrying about charging infrastructure.

Battery Electric Vehicles (BEV)

Battery Electric Vehicles (BEVs), or electric vehicles (EVs), are powered entirely by electricity stored in a large battery pack. BEVs produce zero tailpipe emissions and rely solely on electric motors for propulsion, making them a critical component in reducing carbon emissions and promoting sustainable transportation.

Key Features of BEVs:

• All-Electric Powertrain: BEVs operate solely on electric power, with no internal combustion engine, offering smooth and rapid acceleration.
• Zero Emissions: BEVs produce no tailpipe emissions, contributing to cleaner air and reduced environmental impact.
• Large Battery Pack: BEVs have large lithium-ion battery packs that determine the vehicle’s driving range.
• Regenerative Braking: BEVs capture energy during braking, extending the vehicle’s range by recharging the battery.
• Quiet Operation: BEVs offer a quiet and serene driving experience because they do not have an internal combustion engine.
• Home and Public Charging: BEVs can be charged at home or public charging stations, with charging times varying based on the method.

Typical System Specs:

• Battery Voltage: 300 to 800 volts
• Battery Capacity: 40 to 100 kWh or more
• Electric Motor Power: 100 to 300 kW (134 to 402 hp)
• Torque: 300-700 Nm (221-516 lb-ft) or higher
• Driving Range: 150 to 400 miles (240 to 640 km) on a single charge
• Charging Time: 8 to 20 hours with Level 1, 4 to 10 hours with Level 2, and 30 minutes to 1 hour with DC fast charging

BEVs are ideal for drivers seeking a zero-emission vehicle with lower operating costs and the convenience of home charging. With advancements in battery technology and expanding charging infrastructure, BEVs are increasingly viable for a wide range of driving needs.

Fuel Cell Electric Vehicles (FCEV)

Fuel Cell Electric Vehicles (FCEVs) use hydrogen as their primary energy source. Instead of relying on a battery pack, FCEVs generate electricity through a chemical reaction between hydrogen and oxygen in a fuel cell, which powers the electric motor. This technology produces zero tailpipe emissions, with water vapor as the only byproduct.

Key Features of FCEVs:

• Hydrogen Fuel Cell Powertrain: FCEVs generate electricity from hydrogen, providing propulsion through an electric motor.
• Zero Emissions: FCEVs produce no tailpipe emissions
• Fast Refueling: Refueling a hydrogen tank in an FCEV takes about 3 to 5 minutes
• Long Driving Range: FCEVs are typically comparable to gasoline-powered vehicles
• Quiet and Smooth Operation: FCEVs provide a quiet, smooth driving experience with instant torque and seamless acceleration

Typical System Specs:

• Fuel Cell Voltage: Typically ranges from 200 to 400 volts
• Hydrogen Storage Capacity: Typically 4 to 6 kg of hydrogen stored at high pressure (700 bar or 10,000 psi)
• Electric Motor Power: Often between 100 to 150 kW (134 to 201 hp)
• Torque: Typically provides around 300-400 Nm (221-295 lb-ft)
• Driving Range: Generally between 300 to 400 miles (480 to 640 km) on a full tank of hydrogen
• Refueling Time: Around 3 to 5 minutes at a hydrogen refueling station
• Energy Efficiency: Generally higher than internal combustion engines but lower than BEVs due to the energy required to produce, transport, and store hydrogen.

FCEVs are an eco-friendly option with the convenience of fast refueling and a long driving range. They are particularly suitable for drivers who require a vehicle capable of handling longer trips without frequent stops for recharging.

Transitioning to an electrified vehicle offers significant sustainability and fuel economy benefits, though navigating the diverse options can be complex. Each type of electrified vehicle—from mild hybrids to battery electric and fuel cell vehicles—presents unique advantages and limitations regarding fuel efficiency, emissions, and driving range. By understanding these differences, you can make a more informed decision that aligns with your driving habits, lifestyle, and environmental goals.