Mobile phone chargers had only 2.5-5 watts before, but now we have chargers easily reach 30-65 watts or even higher while maintaining a compact and portable size. What is the mysterious component in this progress?
In response to the modern demand for fast, compact, and convenient charging behavior, many chargers in the market now feature the use of “Gallium Nitride (GaN),.” Gallium Nitride (GaN) is a semiconductor material commonly used in the manufacturing of electronic and optoelectronic components.
The primary reasons for the application of GaN in chargers are its high conversion efficiency, high-frequency operation capability, low heat dissipation, and the ability to achieve compact and lightweight size. It allows chargers to be more portable while delivering efficient high-power charging. (Read More: Is Gallium Nitride (GaN) a “black technology,” or is it just a marketing gimmick?)
Chargers that adopts GaN technology, compared to traditional silicon-based chargers, can more effectively convert power and reduce energy loss. When chargers are designed to be more streamlined and compact, yet capable to fast-charge, they become the ideal travel companions for people in the fast-paced digital domand era.
So, How did GaN chargers evolve?
Let’s take a look at the history of charger development:
Linear Chargers -> Switching Chargers -> GaN Chargers
Linear Charger
Linear charger transforms the standard 110V/220V AC alternating current, using a transformer with different numbers of turns in its “input” and “output” coils. This generates alternating current with a different voltage. The process includes voltage reduction, followed by the conversion of alternating current into direct current, which is then utilized for charging.
Linear charger features a simple design but with lower efficiency. They were often larger, heavier, and had significant energy conversion losses.
Switching Charger
With technological advancements, ‘switching chargers’ gradually replaced linear chargers. It adopted “silicon semiconductor materials” for high-frequency switch transformers. Convert 60Hz AC power to direct current and utilize silicon semiconductor switches to transform the frequency into a high-frequency AC power of 50K Hz. Perform voltage transformation to reduce energy loss, thereby improving efficiency, minimizing heat generation, and reducing the overall size.
GaN Charger
In switch chargers, the use of “silicon semiconductor” can only reach at a certain frequency (around 100k Hz) results in a significant drop in conversion efficiency. Therefore, the focus has shifted to Gallium Nitride (GaN) semiconductor, known for its excellent electrical characteristics (GaN has three times higher energy gap than silicon, and its breakdown voltage limit is ten times higher than silicon).
GaN chargers then have high conversion efficiency, high-frequency operation capability, and low energy dissipation. This material enables chargers to be more compact, lightweight, while providing efficient high-power charging.
The progression from linear to switching chargers and finally to GaN chargers reflects the ongoing advancements in charging technology, aiming for enhanced efficiency, reduced size, and improved performance.
Innergie’s latest upgraded C6 Duo II incorporates GaN components, utilizing Delta Electronic’s “Ancora” 3rd generation GaN semiconductor, offers high efficiency, energy savings, and a compact design that saves space. What makes it even more special is – C6 Duo II has applied Innergie’s exclusive use of Post-Consumer Recycled (PCR) plastics on charger surface, reducing environmental impact in material usage and achieving a significant upgrade in eco-friendly carbon reduction!
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C6 Duo – 63 Watt Dual USB-C Ports
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C-C 1m – 1.8m USB-C to USB-C Cable (PD 240W )
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