2SC2655 Transistor
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2SC2655 Transistor
2SC2655 Transistor
2SC2655 Transistor delivers exceptional performance for electronics manufacturers seeking reliable power amplification and high-speed switching solutions. Designed by Toshiba, this silicon NPN transistor features a low saturation voltage of 0.5V (max) at 1A, ensuring energy-efficient operation in demanding applications. With a maximum collector current of 2A and a collector-emitter voltage of 50V, it is ideal for power amplifiers, industrial control systems, and high-speed switching circuits. The TO-92L package provides excellent thermal management and compact design, making it suitable for space-constrained applications.
2SC2655 Transistor Features
This NPN transistor is engineered for high reliability, offering a transition frequency of 100MHz, which supports RF circuits under 100MHz. Its high collector power dissipation of 900mW ensures robust performance in audio amplification, capable of driving small 1-watt loudspeakers or serving in audio amplifier stages. The 2SC2655 is complementary to the 2SA1020 PNP transistor, enabling versatile circuit designs.
Why Choose the 2SC2655 Transistor
The 2SC2655 transistor is a trusted choice for engineers and OEMs due to its low saturation voltage and high-speed switching capabilities. Its robust TO-92L package ensures durability, while the 70–240 hFE current gain supports small amplifier applications. For long-term performance, operate within 80% of its maximum ratings (1.6A collector current, 40V collector-emitter voltage). This transistor excels in AM/FM broadcasting, industrial automation, and electronic component integration, making it a go-to solution for B2B buyers.
Applications and Compatibility
From high-power LEDs to relays and integrated circuits, the 2SC2655 transistor drives diverse loads in 2A circuits. Its compatibility with the 2SA1020 and equivalents like 2SC3328 and KTC3209 ensures seamless integration into existing designs. Engineers value its high-speed switching time of 1.0μs (typical), which enhances efficiency in power switching applications.
