DESIGN OF AUTOMATIC ELECTRIC DRILLS TO DETECT AND ADJUST DEPTH AND ERGONOMIC LIDAR AND GYROSCOPE BASED
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Abstract
A drilling machine is a tool that moves by rotating a cutting tool used to make a hole in a plane. Usually, electric drills come with attachments that can be used to drill more accurately and precisely. One of the drill attachments
are LiDAR and gyroscope attachments, LiDAR attachment allows drill users to adjust depths and the range of the
drill to a plane and gyroscope to adjust the incline or tilt. Developing such attachments will reduce space for
storage and time to attach a support unit to the drill, it helps users to automatically turn the drills of when it
reaches the length that users desire and adjust the incline or the tilt of the drill. The methods used in developing the automatic drill are analysis and research regarding the parts that will be used on the automatic drill. As well as doing some simulation and experimentation to make sure the integrated parts works as planned. The results of our analysis and research from analyzing the most suitable part to be integrated to the automatic drill design is a digital prototype design in the form of a 3D model design. In conclusion, the integration of LiDAR and gyroscope sensors has significant potential to revolutionize the drilling industry by combining precision, safety, ease of use and eficiency, making it a valuable tool for a wide range of applications and has the potential to be a game changer in
the market.
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