Project

# Title Team Members TA Documents Sponsor
12 Bench Organizer
Liangcheng Sun
Max Mu
Maanas Sandeep Agrawal final_paper1.pdf
grading_sheet1.pdf
other1.pdf
presentation1.pdf
proposal1.pdf
# Bench Organizer
## Team Members:
- Liangcheng Sun (ls25)
- Xiaohu Mu (xiaohum2)
# Problem

Most desk organizers only store items and don’t help users stay organized or productive. People often lose track of small items like pens or keys, which makes working harder. Digital tools exist, but they don’t work well with physical workspaces. We need a better way to help people keep their bench tidy and stay focused.

# Solution

We aim to create a Bench Organizer that detects and tracks items to help users stay organized. It will use RFID technology to know if items like pens are in the right place and send reminders if something is missing. The system will also include a custom PCB to connect and manage all components. The system will also include extra features like a wireless charging pad and Bluetooth notifications if time allows.

# Solution Components

## Item Detection Subsystem

This subsystem will use RFID technology to track items in the organizer. It will incorporate NFC stickers attached to items like pens and keys, and an embedded NFC reader (e.g., PN532 module) in the organizer to detect their presence. The microcontroller (e.g., Arduino Uno) will process the data and check if each item is in its correct spot. This subsystem will send the detection results to the notification subsystem.

## Notification Subsystem

This subsystem will alert users if any items are missing or misplaced. It will use LED lights to indicate the missing items and a buzzer for sound alerts. Additionally, a Bluetooth module (e.g., HC-05) can send notifications to a smartphone or computer. This subsystem will receive data from the item detection subsystem and trigger the appropriate notifications.

## PCB Subsystem

The PCB will be designed and fabricated to integrate all the components of the organizer. It will act as the central hub to connect all other components. This part will ensure proper power distribution to each subsystem, including voltage regulation for different components.

# Criterion For Success

The organizer must detect and track items with at least 90% accuracy in tests. It must notify users when items are missing or misplaced. Additionally, this system should work well under normal indoor lighting. Extra features, if added, should work smoothly without affecting the main functions.

Tesla Coil Guitar Amp

David Mengel, Griffin Rzonca

Featured Project

# Tesla Coil Guitar Amp

Team Members:

* Griffin Rzonca (grzonca2)

* David Mengel (dmengel3)

# Problem:

Musicians are known for their affinity for flashy and creative displays and playing styles, especially during their live performances. One of the best ways to foster this creativity and allow artists to express themselves is a new type of amp that is both visually stunning and sonically interesting.

# Solution:

We propose a guitar amp that uses a Tesla coil to create a unique tone and dazzling visuals to go along with it. The amp will take the input from an electric guitar and use this to change the frequency of a tesla coil's sparks onto a grounding rod, creating a tone that matches that of the guitar.

# Solution Components:

## Audio Input and Frequency Processing -

This will convert the output of the guitar into a square wave to be fed as a driver for the tesla coil. This can be done using a network of op-amps. We will also use an LED and phototransistor to separate the user from the rest of the circuit, so that they have no direct connection to any high voltage circuitry. In order to operate our tesla coil, we need to drive it at its resonant frequency. Initial calculations and research have this value somewhere around 100kHz. The ESP32 microcontroller can create up to 40MHz, so we will use this to drive our circuit. In order to output different notes, we will use pulses of the resonant frequency, with the pulses at the frequency of the desired note.

## Solid-state switching -

We will use semiconductor switching rather than the comparably popular air-gap switching, as this poses less of a safety issue and is more reliable and modifiable. We will use a microcontroller, an ESP 32, to control an IR2110 gate driver IC and two to four IGBTs held high or low in order to complete the circuit as the coil triggers, acting in place of the air gap switch. These can all be included on our PCB.

## Power Supply -

We will use a 120V AC input to power the tesla coil and most likely a neon sign transformer if needed to step up the voltage to power our coil.

## Tesla Coil -

Consists of a few wire loops on the primary side and a 100-turn coil of copper wire in order to step up voltage for spark generation. Will also require a toroidal loop of PVC wrapped in aluminum foil in order to properly shape the electric field for optimal arcing. These pieces can be modular for easy storage and transport.

## Grounding rod -

All sparks will be directed onto a grounded metal rod 3-5cm from the coil. The rest of the circuit will use a separate neutral to further protect against damage. If underground cable concerns exist, we can call an Ameren inspector when we test the coil to mark any buried cables to ensure our grounding rod is placed in a safe location.

## Safety -

Tesla coils have been built for senior design in the past, and as noted by TAs, there are several safety precautions needed for this project to work. We reviewed guidelines from dozens of recorded tesla coil builds and determined the following precautions:

* The tesla coil will never be turned on indoors, it will be tested outside with multiple group members present using an outdoor wall outlet, with cones to create a circle of safety to keep bystanders away.

* We will keep everyone at least 10ft away while the coil is active.

* The voltage can reach up to 100kV (albeit low current) so all sparks will be directed onto a grounding rod 3-5cm away, as a general rule of thumb is each 30kV can bridge a 1cm gap.

* The power supply (120-240V) components will be built and tested in the power electronics lab.

* The coil will have an emergency stop button and a fuse at the power supply.

* The cable from the guitar will use a phototransistor so that the user is not connected to a circuit with any power electronics.

# Criterion for Success:

To consider this project successful, we would like to see:

* No safety violations or injuries.

* A tesla coil that produces small visible and audible 3-5cm sparks to our ground rod.

* The coil can play several different notes and tones.

* The coil can take input from the guitar and will play the corresponding notes.

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