Project Descript_ion

The Arduino Nano 33 IoT Shield for Nixie Clock is an exciting project that combines the power of modern microcontroller technology with the retro charm of Nixie tubes. Nixie tubes are vintage display devices that use neon gas to display numerals, making them a perfect fit for a unique and eye-catching clock. This project aims to create a functional and aesthetically pleasing Nixie clock with modern features and IoT connectivity, using the Arduino Nano 33 IoT board as the core controller.

Project Objectives

• Design and construct a Nixie clock with a visually appealing and retro-futuristic aesthetic.
• Implement precise timekeeping using the DS3231 real-time clock module to drive the Nixie tube display.
• Create a user-friendly interface for setting the time and other clock parameters.
• Incorporate IoT capabilities for remote monitoring and control via Wi-Fi, enabled by the Arduino Nano 33 IoT board.
• Ensure accurate temperature and humidity monitoring using the BME280 sensor.

Components Used

Below is a list of the key components used in this project:

1. Arduino Nano 33 IoT (U1) - The main controller board.
2. DS3231 Real-Time Clock (DS3231) - Provides precise timekeeping.
3. BME280 Temperature and Humidity Sensor (BME280) - Monitors environmental conditions.
4. Nixie Tubes (HV5530) - Vintage display devices for numerals.
5. Voltage Regulator (VR1) - Regulates voltage for the Nixie tubes.
6. Various passive components, including resistors, capacitors, and inductors.
7. Power connectors (PH-3AW) for various functions.
8. Transistors (Q1, Q2, Q3, Q4) for control logic.
9. Schottky Diode (SD1) for voltage protection.
10. LM27313 Voltage Regulator (LM27313) for power regulation.

Project Highlights

• The project combines the aesthetic appeal of Nixie tubes with modern IoT functionality.
• Accurate timekeeping is ensured using the DS3231 real-time clock module.
• The clock offers the convenience of IoT connectivity, allowing remote control and monitoring.
• Environmental conditions are monitored with the BME280 sensor.
• The use of Arduino Nano 33 IoT simplifies programming and enhances versatility.
• Project Implementation:
• The project will involve designing a custom PCB (Printed Circuit Board) to accommodate all the components mentioned above. The Arduino Nano 33 IoT board will serve as the brains of the clock, controlling the Nixie tube display, timekeeping, and IoT functionality. Custom software will be developed to enable users to set the time and configure IoT features.

Schematic And PCB Lyaout

Conclusion

The Arduino Nano 33 IoT Shield for Nixie Clock is a captivating project that brings together classic and contemporary technologies. With IoT connectivity, precise timekeeping, and environmental monitoring, it offers both functionality and aesthetic appeal. This project is an excellent opportunity to explore the fusion of vintage design