Ansys optiSLang Charges Up Innovation at Wolfspeed

“Wolfspeed’s products can run circles around traditional silicon solutions in high-power, high-temperature applications,” says Nelson. “We’re redefining what transistors are capable of.”

Biden’s visit to Durham in March confirmed what many industry experts already know: Wolfspeed is a global force in the movement to transform automobiles from internal combustion engines to electric powertrains. Additionally, the Motor Trend Car of the Year for 2022, the all-electric Lucid Air, features a traction inverter designed by Wolfspeed. It combines an official EPA estimated 516 miles of range with impressive 1,050 horsepower.

Onboard Chargers: An Overlooked but Critical Component

Charging systems for EVs are a key focus for Nelson and his team in the Power Modules business unit at Wolfspeed.

“No one gives much thought to the charging system,” he says. “But if electric vehicles are going to become commonplace, we need to make it much easier to charge them at multiple locations, including at home.”

The solution is to include an onboard charging system on every vehicle that can be easily plugged into any outlet, taking AC current from the car owner’s home and converting it to DC power to recharge the battery. Onboard battery chargers are not only the key to keeping EVs powered, but they are also often capable of harvesting kinetic energy from the vehicle itself to provide additional charge when braking. 

Nelson points out that this system must be optimized for size and weight, to maximize both the vehicle’s range and energy efficiency. However, traditional silicon has made these systems very limited in terms of their output, size, and speed. Enter SiC.

Innovative Products Demand an Innovative Approach

Nelson and his team in Wolfspeed’s Power Modules unit are applying a suite of Ansys solutions, brought together via Ansys optiSLang, to design and verify their package designs for onboard chargers, DC converters, traction inverters, and other components that are essential to widespread EV commercialization.

The team is leveraging a novel optiSLang workflow that integrates electrical simulation in Ansys Electronics Desktop with thermal simulations in Ansys Icepak to create a closed-loop process that predicts the final temperatures in SiC chips installed in a real-world EV operating environment. According to Nelson, this process integration and design optimization solution is ideally suited to the kinds of complex multiphysics studies his team is charged with.

“Electrical properties in chips are highly dependent on junction temperatures, so you can’t look at either aspect of performance in isolation,” Nelson says. “Thermal results need to be mapped directly to the electrical simulation, and the refined power loss estimate needs to be iterated back into the thermal analysis. Ansys optiSLang allows us to converge those simulations and create a true closed loop.”

Ansys Mechanical supports stress and strain analyses, while the addition of Icepak enables a look at stresses caused by thermal expansion. “We even do some base plate curvature optimization to really get the best mechanical and thermal connection possible out of our base plates,” says Nelson.

“Similarly, we do a lot of electrical magnetic analysis of our packages. So, that’s predicting both the inductive and resistive parasitics. We look at the magnetic coupling, especially between the power and signal path. We look at the isolation of the package. And, finally, we optimize thermal properties, especially during events like acceleration, to remove energy and heat out of the device to support high performance.

“We found the tools on the market today to support that kind of closed-loop analysis to be lacking until we discovered Ansys optiSLang could fill in that gap. It allows us to create a kind of digital twin of our packages and look at true system-level performance — how current output is going to affect heat production, and vice versa.”

With the EV market expected to expand to nearly 27 million units by the year 2030, major players in this industry are expected to invest over $350 billion in the near future. Wolfspeed is positioned to play a leadership role with its innovative power device solutions, enabled by Ansys multiphysics simulations.

“Ansys is really driving our package innovations by supporting more advanced and complex power module optimization,” Nelson says. “From the die geometry to the package geometry, Ansys allows us to create our own optimization routines, mappings, and huge optimization sets. We’re really excited about all the future possibilities of the closed-loop design process enabled by Ansys optiSLang — and the level of product innovation it’s going to drive at Wolfspeed.”

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