ALL SYSTEMS NOMINAL — MONITORING FOUR DISASTER CHANNELS 00:00:00
Regional Science Exhibition · Prototype Division

SMART MULTI‑DISASTER
DETECTION & ALERT SYSTEM

A low-cost integrated prototype for early detection of multiple disasters — fire, earthquake, flood and railway track breakage — built entirely from first principles, with no microcontroller, cloud, or internet dependency.

0 Disaster Types Covered
0 Microcontrollers Used
0 % Offline Operation
0 Student Engineers
SEISMIC / SENSOR PULSE LIVE SIM
Fire Earthquake Flood Railway
SCROLL
01 — About the Project

One prototype, four disaster channels

This project is a low-cost disaster alert prototype capable of detecting multiple disasters and immediately alerting people through buzzers. It is designed as a demonstration of how simple, affordable sensing circuits can provide early warning and improve public safety in disaster-prone regions — without relying on expensive electronics or internet connectivity.

🔥

Fire

Flame sensor detects open flame and infrared heat signatures near the monitored zone.

🌍

Earthquake

A pendulum-and-coil mechanism senses ground vibration through physical contact.

🌊

Flood

Conductive probes detect rising water level through changes in circuit conductivity.

🚆

Railway Track Break

A modified IR circuit monitors continuity across an aluminium strip representing the track.

02 — Objectives

What this prototype is built to prove

01

Early Warning

Detect the onset of a disaster event fast enough to give people meaningful time to react.

02

Multi-Hazard Coverage

Combine four independent detection circuits into a single monitored dashboard, instead of one sensor for one hazard.

03

Low Cost & Accessible

Use inexpensive, easily sourced components so the design can be replicated in resource-limited settings.

04

No Dependency

Operate fully offline with no microcontroller, cloud service, or internet connection required to function.

05

Public Safety Awareness

Pair the hardware with clear emergency guidance so detection translates into correct action.

06

Scalable Foundation

Establish a working baseline circuit that can later be extended with smart, connected technology.

03 — Working Principle

How each module detects its hazard

🔥

Fire Detection Module

Purpose: Detect open flame or fire outbreak in the monitored area.

Components

  • Flame Sensor
  • Battery
  • Buzzer

Working

The flame sensor continuously monitors infrared light emitted by fire. The moment it detects a flame, the circuit closes and the buzzer activates immediately, providing an instant audible alert.

Applications

  • Homes & classrooms
  • Kitchens & labs
  • Warehouses

Advantages

  • Instant response
  • Very low cost
  • Simple to maintain
🌍

Earthquake Detection Module

Purpose: Detect ground vibration caused by seismic activity.

Components

  • Copper Coil
  • Hanging Wire
  • Heavy Nut (Pendulum)
  • Battery
  • Buzzer

Working

A heavy nut hangs freely on a wire like a pendulum, positioned near a copper coil. During ground vibration, the pendulum swings and touches the coil, completing the circuit and triggering the buzzer.

Applications

  • Seismic zones
  • School buildings
  • Storage facilities

Advantages

  • Purely mechanical
  • No calibration needed
  • Works without power sensors
🌊

Flood Detection Module

Purpose: Detect rising water levels before they become dangerous.

Components

  • Water Level Sensor
  • Battery
  • Buzzer

Working

Exposed probes on the water level sensor detect conductivity once submerged. When water reaches the probes, current flows through the water, closing the circuit and sounding the buzzer.

Applications

  • Flood-prone basements
  • Riverside settlements
  • Drainage systems

Advantages

  • Direct water contact detection
  • Reliable in monsoon zones
  • Easy to reposition
🚆

Railway Track Break Module

Purpose: Detect a break in track continuity that could derail a train.

Components

  • Modified IR Sensor
  • Aluminium Strip
  • Battery
  • Buzzer

Working

An aluminium strip represents a section of railway track. A modified IR-based circuit constantly checks for continuity across the strip. If the strip breaks or separates, continuity is lost and the buzzer rings.

Applications

  • Rail track monitoring
  • Bridge joints
  • Structural continuity checks

Advantages

  • Continuous monitoring
  • Fast fault detection
  • Simple to replicate
04 — Modules

Component inventory, by module

ModuleSensorTrigger MechanismOutput
Fire Flame Sensor Infrared flame detection Buzzer (instant)
Earthquake Copper Coil + Pendulum Physical contact on vibration Buzzer (on contact)
Flood Water Level Sensor Conductivity across probes Buzzer (on submersion)
Railway Modified IR Sensor Loss of strip continuity Buzzer (on break)
05 — Live Dashboard

Control room simulation

This dashboard simulates how the physical prototype reports status. Trigger a scenario below to see the alert flow.

OVERALL RISK LEVEL LOW
No active alerts — all channels nominal
🔥 SAFE

Fire Status

Flame sensor reading normal. No thermal signature detected.

🌍 SAFE

Earthquake Status

Pendulum stable. No coil contact registered.

🌊 SAFE

Flood Status

Water level below probe threshold.

🚆 SAFE

Railway Status

Track strip continuity confirmed.

07 — Team

Class IX Charlie

Team Leader
SH

Sanchit Hooda

Led system design, module integration and dashboard concept.

Member
YS

Yash Sehrawat

Focused on circuit assembly and sensor calibration.

Member
VO

Veer Ohlan

Handled testing, documentation and exhibition presentation.

08 — Emergency Guide

What to do when an alert sounds

🔥

Fire Safety

  • Stay low to avoid smoke inhalation.
  • Use the nearest safe exit, never a lift.
  • Alert others and call for help immediately.
  • Do not re-enter the building for belongings.
🌍

Earthquake Safety

  • Drop, Cover, and Hold On under sturdy furniture.
  • Stay away from windows and heavy fixtures.
  • If outdoors, move to open ground away from buildings.
  • Expect aftershocks — remain alert after the first tremor.
🌊

Flood Safety

  • Move to higher ground immediately.
  • Avoid walking or driving through moving water.
  • Switch off electrical mains if water is rising indoors.
  • Keep emergency supplies and documents accessible.
🚆

Railway Safety

  • Never attempt to cross a track showing a fault signal.
  • Alert station staff or the nearest railway official.
  • Keep a safe distance from the flagged section.
  • Follow posted signals and announcements at all times.

Emergency Contacts (demo)

Fire: 101 Police: 100 Ambulance: 108 Disaster Helpline: 1078
09 — Future Scope

Future Scope

Everything in this section is future work only — none of it is part of the current prototype.

🤖

AI Disaster Prediction

Predictive models trained on historical sensor data to forecast risk before an event occurs.

📡

IoT Monitoring

Networked sensors reporting continuously to a central monitoring hub.

✉️

SMS Alert System

Automatic text alerts sent to residents and authorities the moment a hazard is detected.

📍

GPS Tracking

Location-tagged alerts so response teams know exactly where to act.

☁️

Cloud Dashboard

Remote access to live status from anywhere via a secure cloud platform.

📱

Mobile Application

A companion app for real-time push notifications and history logs.

🛰️

Satellite Monitoring

Wide-area hazard tracking using satellite imagery for regional coverage.

🏛️

Government Integration

Direct data feed into official disaster management authority systems.

🧠

Machine Learning

Pattern recognition that reduces false alarms and improves detection accuracy over time.

🚁

Drone Surveillance

Aerial verification and damage assessment immediately after an alert.

🏢

Emergency Control Room

A dedicated response center coordinating alerts across all monitored zones.

10 — Contact

Reach the team

Project Enquiries

For questions about the prototype, methodology or exhibition demonstration, reach out to the team leader.

Sanchit Hooda — Team Leader

Class IX Charlie

Send a Message

This is a demo form for the exhibition prototype and does not send real messages.