• ButterFlyback AC/DC Converter

    ButterFlyback AC/DC Converter

    110V-130V to 15V @ 3A AC/DC Flyback Converter.

    ryanf

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    2 years ago

    0 Uses

    177 Comments

    4 Stars


  • ZVS Flyback Driver

    ZVS Flyback Driver

    Simple ZVS Flyback driver circuit.

    2 years ago

    0 Uses

    0 Comments

    2 Stars


  • Smart CDI Motorcycle ECU

    Smart CDI Motorcycle ECU

    High-performance ESP32-based smart CDI / motorcycle ECU with automotive 12V transient protection, flyback HV capacitor charging, isolated SCR firing, VR pickup input, analog sensors, and auxiliary low-side outputs.

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    25 days ago

    0 Uses

    0 Comments

    1 Star


  • Realistic Brown Battle Mech

    Realistic Brown Battle Mech

    Nice — you can do a clean pulse + latch using a single quad Schmitt-NAND chip: 74HC132 (or 74LVC132 for 3.3 V systems). The HC132 contains four 2-input NAND gates with Schmitt inputs so you can both clean a noisy SYN480R DATA line and build an SR latch (NAND SR is active-LOW) inside one package. Only a few passives and a driver transistor are needed. Below is a ready-to-build recipe (parts, wiring, explanation, tuning tips, and an ASCII schematic) — no extra logic ICs required. Parts (per latch) 1 × 74HC132 (quad 2-input NAND with Schmitt inputs). If your system is 3.3 V use 74LVC132 / 74HC132 rated for 3.3 V. Rin = 47 kΩ (input series) Cfilter = 10 nF (input RC to ground) — tweak for debounce/clean time Rpulldown = 100 kΩ (pull-down at input node, optional) Rpullup = 100 kΩ (pull-up for active-LOW R input so reset is idle HIGH) Rbase = 10 kΩ, Q = 2N2222 (NPN) or small N-MOSFET (2N7002) to drive your load Diode for relay flyback (1N4001) if you drive a coil Optional small cap 0.1 µF decoupling at VCC of IC Concept / how it works (short) Use Gate1 (G1) of 74HC132 as a Schmitt inverter by tying its two inputs together and feeding a small RC filter from SYN480R.DATA. This removes HF noise and provides a clean logic transition. Because it's a NAND with tied inputs its function becomes an inverter with Schmitt behavior. Use G2 & G3 as the cross-coupled NAND pair forming an SR latch (active-LOW inputs S̄ and R̄). A low on S̄ sets Q = HIGH. A low on R̄ resets Q = LOW. Wire the cleaned/inverted output of G1 to S̄. A valid received pulse (DATA high) produces a clean LOW on S̄ (because G1 inverts), setting the latch reliably even if the pulse is brief. R̄ is your reset input (pushbutton, HT12D VT, MCU line, etc.) — idle pulled HIGH. Q drives an NPN/MOSFET to switch your load (relay, LED, etc.). Recommended wiring (pin mapping, assume one chip; use datasheet pin numbers) I’ll refer to the 4 gates as G1, G2, G3, G4. Use G4 optionally for additional conditioning or to build a toggler later. SYN480R.DATA --- Rin (47k) ---+--- Node A ---||--- Cfilter (10nF) --- GND | Rpulldown (100k) --- GND (optional, keeps node low) Node A -> both inputs of G1 (tie inputs A and B of Gate1 together) G1 output -> S̄ (S_bar) (input1 of Gate2) Gate2 (G2): inputs = S̄ and Q̄ -> output = Q Gate3 (G3): inputs = R̄ and Q -> output = Q̄ R̄ --- Rpullup (100k) --- VCC (reset is idle HIGH; pull low to reset) (optional) R̄ can be wired to a reset pushbutton to GND or to an MCU pin Q -> Rbase (10k) -> base of 2N2222 (emitter GND; collector to one side of relay coil) Other side of relay coil -> +V (appropriate coil voltage) Diode across coil If you prefer MOSFET low side switching: Q -> gate resistor 100Ω -> gate of 2N7002 2N7002 source -> GND ; drain -> relay coil low side

    10 months ago

    0 Uses

    0 Comments

    1 Star


  • Brainstorm a new project with AI [Example]

    Brainstorm a new project with AI [Example]

    1. Empieza con el objetivo Ejemplo: “Estoy creando un módulo de control para una bomba de aire de 24 V en una máquina CNC láser. El circuito debe encender y apagar la bomba según la señal FAN que viene de la tarjeta de control (3.3 V o 5 V).” 2. Explica los requerimientos La bomba trabaja a 24 V y hasta 2 A. El control debe ser con un MOSFET N–channel en conmutación. Debe incluir protección contra picos y ruidos eléctricos. Se deben mostrar indicadores LED (encendido, funcionamiento, error). 3. Lista de funciones que quieres en el diseño Protección: fusible, diodo flyback, TVS, snubber RC. Control: MOSFET con resistencia de gate y pull-down. Filtrado: capacitores cerca de la bomba. Indicadores LED: Azul: energía 24 V presente. Verde: bomba activa. Rojo: error o apagado. 4. Explica la lógica de funcionamiento (qué debe pasar) Cuando la fuente 24 V se conecta → LED azul enciende. Cuando la señal FAN activa el MOSFET → bomba enciende + LED verde enciende. Cuando la bomba está apagada → LED rojo puede encender (opcional). Si ocurre sobrecorriente → el fusible abre el circuito. 5. Diagrama de bloques sencillo (texto) [FUENTE 24V] -- [FUSIBLE] --+--> [BOMBA] --> [MOSFET] --> GND | +--> [LED Azul] --> GND [SALIDA FAN] --> [Res 100Ω] --> [Gate MOSFET] [Gate MOSFET] --> [Pull-down 100kΩ a GND] [Protecciones: Diodo, TVS, RC, Capacitores en paralelo con la bomba]

    10 months ago

    0 Uses

    0 Comments

    1 Star


  • Flyback

    Flyback

    A simulated circuit that demonstrates how diodes in a bridge configuration convert an AC voltage to DC voltage.

    3 years ago

    0 Uses

    3 Comments

    0 Stars


  • Playground: ButterFlyback AC/DC Converter

    Playground: ButterFlyback AC/DC Converter

    110V-130V to 15V @ 3A AC/DC Flyback Converter.

    2 years ago

    0 Uses

    66 Comments

    0 Stars


  • High Voltage Power Supply V1

    High Voltage Power Supply V1

    24VDC Input 5kV Output MCU controlled 200kHz PWM Mosfet based inverter 6 stage multiplier Todo: Pick real inductor in load network Flyback Transformer with Ferrite core Selection

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    a month ago

    0 Uses

    55 Comments

    0 Stars


  • ButterFlyback AC/DC Converter dCJm

    ButterFlyback AC/DC Converter dCJm

    110V-130V to 15V @ 3A AC/DC Flyback Converter.

    2 years ago

    0 Uses

    3 Comments

    0 Stars


  • ButterFlyback AC/DC Converter gxoR

    ButterFlyback AC/DC Converter gxoR

    110V-130V to 15V @ 3A AC/DC Flyback Converter.

    2 years ago

    0 Uses

    1 Comment

    0 Stars


  • Compact ESP32 Drone Motor Driver

    Compact ESP32 Drone Motor Driver

    Compact 2-layer driver board for four coreless mini-drone motors using AO3400 MOSFETs, SS14 flyback diodes, JST-PH battery input, motor solder pads, and external ESP32 PWM wiring.

    17 days ago

    0 Uses

    0 Comments

    0 Stars


  • 10-Channel 24V Relay AC Distribution Board

    10-Channel 24V Relay AC Distribution Board

    10-channel relay board for externally protected AC live switching with 24V coil drive harness, per-channel fuses, direct neutral/PE distribution, and local relay flyback protection.

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    4 days ago

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    0 Stars


  • 5V Omron G2RL Relay Driver

    5V Omron G2RL Relay Driver

    5 V Omron G2RL relay driver PCB using an MMBT2222A low-side transistor, input terminals, flyback diode, and screw-terminal relay output.

    a month ago

    0 Uses

    0 Comments

    0 Stars


  • 12V 555 Ignition Coil Driver

    12V 555 Ignition Coil Driver

    12 V NE555 astable ignition-coil driver using an IRF840 MOSFET low-side switch with gate conditioning, decoupling, input/output connectors, and flyback clamp protection.

    a month ago

    0 Uses

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    0 Stars


  • DER-920 LED Driver Reference

    DER-920 LED Driver Reference

    Unconnected DER-920 65 W offline LED ballast component schematic grouped by input/EMI, PFC boost, isolated flyback, secondary control/dimming, and connectors. Components are intentionally not wired yet.

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    2 months ago

    0 Uses

    0 Comments

    0 Stars


  • Open Hornet 16-Channel 28V Magnetic Hold Driver

    Open Hornet 16-Channel 28V Magnetic Hold Driver

    Open Hornet 16-channel 28 V magnetic-hold coil driver for Honeywell ET switches. Arduino Mega/Pro Micro logic inputs drive low-side 100 V MOSFET channels for ET switch magnet coils with common ground, fail-safe pulldowns, 100 V flyback protection, dedicated 28 V coil input, and conservative high-current 4-layer PCB routing.

    a month ago

    0 Uses

    0 Comments

    0 Stars


  • Fragile Black Sonic Screwdriver

    Fragile Black Sonic Screwdriver

    300 W universal-input isolated offline SMPS based on a modified ATX-style architecture. Universal 115-230 VAC, 50/60 Hz input via fused IEC C14 inlet. Outputs: +12 V at 20 A, +5 V at 14 A, +3.3 V at 12 A, +5 Vsb at 2.5 A, and -12 V at 0.3 A. Includes primary rectification with GBU806 bridge, bulk capacitors, bleeders, snubbers, main PWM and driver transformer, standby flyback, optocoupler and TL431 feedback, supervisor logic, test points, fan and heatsink provisions, and 2-layer FR-4 PCB layout with 8 mm primary-secondary isolation and heavy copper routing on high-current rails.

    4 months ago

    0 Uses

    0 Comments

    0 Stars


  • Fine Orange Interocitor

    Fine Orange Interocitor

    True 4-Layer 2 oz Copper Scanner Head PCB with 28 Luddite_Coil_8mm Multilayer 8 mm OD Square Spiral Coils in a 2×14 Grid, 12 mm×18 mm Pitch, Individual MOSFET Drivers and Flyback Diodes per Coil, Bottom Layer Kept Component-Free #Luddite_Coil_8mm #2x14Grid #4Layer2Oz #CoilArray

    5 months ago

    0 Uses

    0 Comments

    0 Stars


  • ACE10W_MW

    ACE10W_MW

    10 W IEC 62368 Class II Isolated Flyback AC/DC Converter (85–305 Vac to 5 V @ 2 A, 80% Efficiency, 6 mm Creepage, EE-Core Transformer, 90 °C Ambient) #flyback #classII #EEcore

    5 months ago

    0 Uses

    0 Comments

    0 Stars


  • ButterFlyback AC/DC Converter 08c8

    ButterFlyback AC/DC Converter 08c8

    110V-130V to 15V @ 3A AC/DC Flyback Converter.

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    a year ago

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    0 Stars


  • Prepared Salmon Liquid Breathing Apparatus

    Prepared Salmon Liquid Breathing Apparatus

    This project is focused on designing a highly efficient PCB for a switching power supply using a robust selection of electronic components. Our design leverages a flyback topology featuring a ferrite transformer (options EE25 or EE33), a PWM integrated circuit (TL494, SG3525, or UC3842), and a power MOSFET (IRF840 or a similar alternative) for effective high-voltage switching. Fast and reliable rectification is ensured by using a Schottky diode (MBR20100 or FR107) along with a rectifier bridge built from four 1N4007 diodes or a dedicated 4A bridge. Key stabilization and regulation components include the TL431 reference regulator and a Zener diode for precise voltage control in critical areas. For input and output filtering, the design incorporates electrolytic capacitors (470 µF, 25 V for output and 400 V, 100 µF for input) and ceramic capacitors (ranging from 1 nF to 100 nF) to limit high-frequency noise. Additional safety and operational features are provided by an NTC (soft-start thermistor) to prevent current spikes, various resistors (from 1 Ω to 100kΩ), an optocoupler (PC817) for signal isolation, a switch, and a protection fuse. Before moving forward with a finalized PCB layout and schematic details, we need to clarify a few design choices: 1. Transformer Choice: Would you prefer using the EE25 or the EE33 ferrite transformer variant as the heart of the switching power supply design? This detailed approach ensures that the power supply not only meets rigorous performance and safety standards but also supports a reliable and scalable solution for various electronic applications. #PCBDesign #SwitchingPowerSupply #Electronics #SMPS #PowerElectronics #FlybackConverter #CircuitDesign #ElectronicsComponents

    a year ago

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    0 Stars


  • Decisive White Flux Capacitor

    Decisive White Flux Capacitor

    This project involves designing a complete schematic for a robotic arm controller based on the ESP32-C3 microcontroller, specifically using the ESP32-C3-MINI-1-N4 module. The design features a dual power input system and comprehensive power management, motor control, I/O interfaces, and status indicators—all implemented on a 2-layer PCB. Key Specifications: Microcontroller: • ESP32-C3-MINI-1-N4 module operating at 3.3V. • Integrated USB programming connections with reset and boot mode buttons. Power System: • Dual power inputs with automatic source selection: USB-C port (5V input) and barrel jack (6-12V input). • Power management using LM74610 smart diode controllers for power source OR-ing. • AMS1117-3.3 voltage regulator to deliver a stable 3.3V supply to the microcontroller. • Filter capacitors (10μF electrolytic and 100nF ceramic) at the input and output of the regulators. • Protection features including USBLC6-2SC6 for USB ESD protection and TVS diodes for barrel jack overvoltage protection. Motor Control: • Incorporates an Omron G5LE relay with a PC817 optocoupler and BC547 transistor driver. • Provides dedicated header pins for servo motors with PWM outputs. • Flyback diode protection implemented for relay safety. I/O Connections: • Header pins exposing ESP32-C3 GPIOs: Digital I/O (IO0-IO10, IO18, IO19) and serial communication lines (TXD0, RXD0), plus an enable pin. • Each I/O pin includes appropriate 10kΩ pull-up/pull-down resistors to ensure reliable performance. Status Indicators: • A power status LED with a current-limiting resistor. • A user-controllable LED connected to one of the GPIO pins. PCB Layout Requirements: • 2-layer PCB design with separate ground planes for digital and power sections. • Placement of decoupling capacitors close to power pins to reduce noise. • Adequate trace width for power lines to ensure efficient current flow. • Inclusion of mounting holes at the board corners for secure installation. • All components are properly labeled with correct values for resistors, capacitors, and other passive elements, following standard design practices for noise reduction, stability, and reliability. #RoboticArmController #ESP32C3 #SchematicDesign #PCBDesign #ElectronicsDesign #PowerManagement #MotorControl #EmbeddedSystems #IoT

    a year ago

    0 Uses

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    0 Stars


  • Shashank

    Shashank

    The buck–boost converter is a type of DC-to-DC converter that has an output voltage magnitude that is either greater than or less than the input voltage magnitude. It is equivalent to a flyback converter using a single inductor instead of a transformer.Two different topologies are called buck–boost converter

    2 years ago

    0 Uses

    0 Comments

    0 Stars