Auto Electrification Boosts Modular Designs

Article By : Maurizio Di Paolo Emilio

With growing investment in electrification, power technologies will play a key part in boosting drivetrain efficiency.

Electric vehicles currently constitute about 11 percent of global vehicle production, a total that is expected to jump to 62 percent by 2030. About half are expected to be fully electric.

Credit Suisse projects about 63 million new vehicles worldwide by the beginning of the next decade, with an estimated 29 being all-electric. Industry observers note that growing power demand will further strain electrical grids.

In an interview, with Patrick Wadden, vice president of Vicor Corp.’s Automotive Business Development unit, stressed the need for strong investment in electrification and power technologies that will play a key role in solving powertrain efficiency challenges.

“Volvo is claiming that 50 percent of their vehicles will be electric, and the remaining ones are going to be hybrid by 2025. By 2030, Ford, GM and Chrysler are going to be investing over $50 billion. This year new vehicle estimates are even higher than last year,” Wadden added.

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By 2030, battery electric vehicles (BEV) will account for 45% of all xEVs (Source: Credit Suisse estimates.)

Car makers are electrifying some of their most popular vehicles, including the new Ford Mach E (the electric Mustang) and its flagship F150 truck, dubbed Lightning. The new vehicles include fast-charging technology while promising lower maintenance costs.

Power demand

Electric power levels in cars with internal combustion engines typically range from 600W to 3kW. New EVs require power levels ranging from 3 to 60 kW, or up to 20 times that of conventional vehicles. The increase represents a major challenge for power engineers trying to optimize power delivery networks. To meet those challenges, Wadden emphasized the need for lightweight, compact systems offering flexibility so power components can easily scale and be reused across fleets.

To maximize vehicle electrification, OEMs must increase power levels, reduce powertrain size and weight while improving thermal management and reusability. The choice of powertrain and charging is critical. Manufacturers are striving to optimize their power networks by investing millions of dollars in electrification R&D while iterating with new technology. For example, 48-V power supply technology is rapidly expanding, both for fully electric and hybrid vehicles.

Modular advantages

OEMs need to pack as much power as possible into a constrained space. “Vehicles need compact and efficient power solutions,” said Wadden. To achieve full-fleet electrification, OEMs need to be able to reuse designs across different platforms to speed deliveries. Scaling is essential when modifying power levels among sedans, minivans and SUVs that share the same platform.

Overall vehicle weight affects performance, particularly battery life. Vicor is pitching a modular bus converter (BCM6135) billed as providing 98-percent efficiency via electrical interference filtering, decreased cooling and a 25kg 48-V battery replacement case. The 61-by-35-by-7mm power module converts the primary battery from up to 800V to 48V, delivering more than 2kW of power with a power density of >4.3kW/in3.

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Power delivery networks using power modules reduce size and weight. (Source: Vicor)

As vehicle electrification advances, design teams increasingly must consider changing power requirements. Wadden said a scalable, modular power system allows designers to implement standard approaches in a variety of EV powertrains. Modularity also allows distributed power architectures using a 48-V bus. Power modules can be placed in alternate locations for localized 48-V/12-V conversion–for example, in a glove compartment, trunk or near each wheel.

Wadden added that qualification of vehicle electronic components represents a common delay in development. Delays can run up to three years. Hence, high-density power modules are promoted as reducing design qualification times.

“Innovation is needed in the form of new architectures and topologies that provide maximum performance today and can also be reused and reconfigured for the future,” said Wadden. “Integration is important. If you look at one of our modules that has 200 individual components inside, it’s a lot easier to qualify one module than it is 200 components. And so integration has a lot of merits.”

Many EVS are now using 800-V primary batteries to meet the required power levels and deliver higher performance. Existing converters are bulky due to the high input-to-output voltage (800V to 48V) ratio. Fixed-ratio conversion modules like Vicor’s, operating at high switching frequencies, offer efficiencies of up to 98 percent, thereby reducing system size and weight. Decentralized architectures and modular power supplies for the distribution of the 48-V power can help simplify designs.

Modules also can be connected in parallel. With the addition of a few others components, it is possible to boost a power delivery network from a few hundred watts to tens of kilowatts.

Power modules deliver distinct advantages, promising higher power density, flexibility and faster power system design.

This article was originally published on EE Times.

Maurizio Di Paolo Emilio holds a Ph.D. in Physics and is a telecommunication engineer and journalist. He has worked on various international projects in the field of gravitational wave research. He collaborates with research institutions to design data acquisition and control systems for space applications. He is the author of several books published by Springer, as well as numerous scientific and technical publications on electronics design.

 

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