Use 3D printed parts, basic electronic components, and step-by-step instructions to build your own GearBug. Adapt your GearBug for fun challenges including drag races, hill climbs, or just plain cool looks!
***see GearBug_Assembly_Instructions-Explore_Making.pdf in Thing Files
Note: Hardware Kits can be ordered from ExploreMaking (contact for details)
3D Printed Parts plus Hardware Kits can be ordered from ExploreMaking (contactfor details)
The GearBug is designed using SolidWorks. Many advanced design techniques were used to design the part, but one key technique that is important for the designs functionality is sliding-fit parts (the axles that must slide in the axle shafts). To design these parts we left a 1mm gap between the axle and the axle shafts. The axles are 7mm in diameter and the axle shafts are 8mm in diameter.
We created a fun and engaging vehicle after searching for an introductory project with broad appeal. The initial GearBug is easy to assemble but also provides opportunities for math and physics lessons as well as design challenges.
• Follow instructions to create a functional GearBug
• Demonstrate understanding of an electrical circuit to power the GearBug
• Adapt the GearBug for challenges of speed and hills
• Comprehend the relationship between gear ratios and speed/power
• Design a cover to change the appearance of GearBug
Students can work in groups of 2 or 3, promoting teamwork and reducing material costs. If teams used, we recommend having the students switch roles every 5 to 10 minutes so all students assemble, read, and document. One suggestion for homework is the documentation of their process.
We've worked hard to create a step by step assembly guide and resources. Please also see Resources section and Thing files.
You can extend the lessons by including challenges for the GearBug (what gear ratio is fastest, most powerful?). For more advanced groups, students can calculate the speed based on gear ratios and/or design new gears for GearBug. For art classes, students can create shells or other fun additions to give their GearBug different characteristics.
- 3D printed parts (as uploaded here)
- double-sided tape
- battery holder
- 10 x #2 screws
- motor (size 130 DC toy motor)
- gear ratios
- speed/power rel'nship
One hour is sufficient for basic activity. The extensions can take 30 minutes to several hours depending on the depth and number of extensions added.
Students could be assessed on the following:
• Documentation of the process
• Completed GearBug that can race others
• Understanding of the relationship between gear size and speed/power