BOSON Smart Science Pack - Earthquake Challenge

We all know how do earthquakes occur and what destruction they cause. But as for now, we cannot predict exactly when an earthquake will happen. So the earthquake-resistant design is becoming the new form in most earthquake-prone cities.

This earthquake working model, made of BOSON Smart Science Pack-Earthquake Challenge, is well applicable to study how to improve the buildings earthquake-proof level.

Build & Test Earthquake Proof Buildings | BOSON Smart Science Projects

This earthquake working mode combines a shake table and earth-proof structures from simple materials and BOSON modules.

The model simulates seismic ground motion during an earthquake. With a rotation sensor, you can change the speed of the motor to generate movement at different frequencies. It will be inspiring to test the effect of short and high-frequency earthquakes on buildings.

A nature earthquake creates motions on 3 axes, but since our shake table is moving along the same direction, it will be easy to measure the acceleration on the X-axis with a micro:bit, to give you an accurate result of how strong the earthquake is. Fix the micro:bit at the top of the building, plug it with your computer, open Mind+, and let the data fly.

Then, we can try different shapes/heights/weights to figure out the best solution to earthquake-proof structures.

Note: Not include materials like micro:bit, Box & Cardboard, Straws, Pipe cleaners, Bottle caps, Bubber bans, Thumbtack, etc.

Features:

• Plug-and-play

• Reusable

Applications:

• STEAM education

• Earthquake working model

• Ground motion simulation

• Study on Earthquake-resistant structures

Specifications:

• Operating Voltage: 4.5V-5.5V

• Dimension: 60 x 220 x 300mm/2.36 x 8.66 x11.8”

• Weight: 300g

Documents:

• Build & Test Earthquake Proof Buildings

Shipping List:

• Mainboard-1 IO x1

• Motor Controller Module x1

• Boson: Rotation Sensor x1

• 3xAAA Battery Holder x1

• Boson: Micro Metal Gear Motor x1

• Cable 10cm x2

• Package Box x1