Guidebook on Enhancing Electric Mobility: Boosting Duration Using Dense Power Conversion Techniques
In the rapidly evolving world of eMobility, traditional power solutions often struggle to meet the demanding requirements of compact size, high efficiency, and thermal management. A new eBook, however, offers a solution: high-performance power modules. This comprehensive guide focuses on developing power delivery networks for eMobility products, teaching the use of these advanced power modules to overcome design challenges.
The eBook does not provide details about the specific power modules it discusses, nor does it mention any particular eMobility products it focuses on. Instead, it delves into the modular power approach as a solution for 48V power architecture electrification challenges.
High-performance power modules offer several advantages that help shorten time-to-market for eMobility products. By integrating advanced power conversion, these modules enhance system efficiency, reduce heat, and improve reliability.
Compact integration is one key way these modules address design challenges. By reducing system size and complexity, they are critical for space-constrained eMobility platforms. Improved efficiency and thermal management lead to less energy loss and simpler cooling solutions, enhancing reliability and reducing system costs.
Modular design is another significant advantage. Modular power systems allow quick assembly, easy maintenance (such as "hot swap" module replacement under 10 minutes), and scaling power delivery up or down as needed. This flexibility simplifies complex power architecture challenges common in electrification, enabling developers to accelerate design cycles and optimize performance while extending runtime in vehicles.
Advanced semiconductor technologies, like silicon carbide (SiC), are also leveraged in these high-performance modules. SiC enables higher switching frequencies, less energy dissipation, higher power density, and robustness to high voltages and temperatures. Ultimately, this results in longer driving range and lighter, cost-effective EV design.
The eBook includes four case studies on the application of high-performance power delivery networks in various eMobility platforms. Each case study aims to address power challenges and extend runtime, demonstrating real-world implementations of these power modules.
Supporting examples from industry include BENNING’s BELATRON modular rapid-charging systems, which combine high operational safety, energy efficiency, and modularity to minimize installation time, reduce maintenance downtime, and optimize user space. This ensures fast deployment of charging infrastructure for EVs.
While no other dedicated case studies or articles were explicitly detailed in the search results, the references point to an active, evolving field where modular, high-performance power electronics—especially leveraging SiC technology—are critical enablers of the eMobility transition, reducing design complexity and accelerating time-to-market.
In summary, high-performance power modules facilitate overcoming eMobility design challenges by enabling compact, efficient, and scalable power delivery, simplifying thermal management, supporting modular maintenance and upgrades, and leveraging semiconductor advances for superior performance. These advantages contribute to faster development and deployment of eMobility products and charging infrastructure.
Unfortunately, the eBook does not provide information about its authors, publishers, or the cost of the power modules or the eBook itself. Despite this, the eBook remains a valuable resource for those seeking to navigate the complex world of eMobility power delivery and accelerate their product development.
Technology and data-and-cloud-computing play significant roles in the eBook, which focuses on high-performance power modules for eMobility products. The eBook leverages advanced semiconductor technologies like silicon carbide (SiC) in these power modules, which are crucial enablers of the eMobility transition due to their ability to support higher switching frequencies, less energy dissipation, higher power density, and robustness to high voltages and temperatures. Furthermore, the eBook illustrates the advantages of modular power systems, which can be designed, maintained, and upgraded more efficiently using data analysis and cloud-based tools.
