Energy harvest from Current Transformer and store in a Supercapacitor. Simulation and PCB. See https://www.ti.com/lit/ug/tidud59/tidud59.pdf

I want to blow up a MOSFET gloriously. Basically supercapacitor onto MOSFET with a gate flipping setting.

Solar panel power converter with supercapacitor backup. Based on the AEM10941 chip from ePeas.

This is a board for energy-efficient projects, based on STM32 with a BQ25570 controller and a temperature humidity sensor. There is also a display and a supercapacitor in the role of power supply #MPPT #solar #STM32 #ti

Piggyback USB2.0 Type-A Mezzanine Interposer with Reverse-Current Protection, Tamper-Resistant D+/D− One-Shot Shunt, Supercap Backup, and SI-Compliant Chassis-Mounted Shielding

This project aims to design and develop a modular monitoring system for a LiC supercapacitor array, incorporating PCBs A and B for voltage sensing on either side of the array, and PCB C for central control. PCBs A and B will measure cell voltages, communicate data via I2C, and feature activity/status LEDs, powered directly from the array. PCB C will aggregate data, managing over/under voltage, overcurrent, and balancing. The goal is a compact, efficient solution to ensure the array's safety and longevity.

This is an NFC card that works from the solar. On the board, there are two solar panels that accumulate energy through the controller in the supercapacitor. The NFC controller itself can be programmed via the microcontroller on the board #solar #nfc #stm32 #iot

12 V Automotive UPS-Style Supercapacitor Power Stabilizer

Etapa 1: Recolección y Almacenamiento de Energía Entrada: tus cactus en serie (ej. 15 cactus × 0.5 V = 7.5 V). Componente clave: Supercapacitor o batería recargable de baja capacidad (Li-ion o LiFePO4, 3.7V-7.4V). Diodo Schottky entre los cactus y el capacitor para evitar descarga inversa. 🛠 Ejemplo de componentes: Supercapacitor de 5–10 F, 5.5 V o batería de 3.7 V (tipo 18650). Diodo Schottky 1N5819. Módulo cargador TP4056 (si usas batería). Etapa 2: Aumento de Voltaje (Boost Converter) Conversión de 3.7 V / 7.5 V DC a 110 V AC. Necesitas: Boost Converter (DC-DC Step-up) de hasta 300 V DC. Inversor DC-AC (pequeño, tipo mini inverter para LEDs) que convierta ese voltaje a 110 V AC. NOTA: Algunos focos LED pueden funcionar con 110 V DC directamente, si quieres evitar el inversor. Etapa 3: Detección de Noche Sensor LDR (resistor dependiente de luz) conectado a un comparador (ej. LM393) o a un microcontrolador (como un ATtiny o ESP8266 si quieres funciones extra). Al bajar la luz solar: El comparador activa un MOSFET o un relé que conecta la energía almacenada al foco.

800-mA Linear Charger for 1- to 4-Cell Supercapacitor, 40-V load-dump tolerant to support charging backup supercapacitor, 3-V to 18-V operating Integrated fault protection – 18-V IN overvoltage protection – 1000-mA overcurrent protection – 125°C thermal regulation; 150°C thermal shutdown protection – ISET pin short protection

Supercapacitors / Ultracapacitors 2.7V 50F 18X40mm Radial Custom made footprint from Datasheet dimensions. Not compliant to any standards. No 3D Model #capacitor #part

Solar panel power converter with supercapacitor backup. Based on the AEM10941 chip from ePeas.