Unmanned Aerial Vehicle

Fields of application:


UAV Pilot Training

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* The RC device
may look different

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  • Training and methodology complex
  • Airplane and quadcopter hybrid
  • Material of the support structure, wings, stabilizer: PLA or PETG, 3D printing
  • Wingspan: 380 mm
  • Take-off weight: 140g
  • Flight time: 8 minutes
  • Signal loss safety measure: motor stop
  • Collision resistance: withstands a drop from a 5-m height, fully repairable

FIXAR EDU applications

Professional drone

Fixar EDU will teach you how to design, configure and operate unmanned airplane systems! This is a unique complex with an aerial device for training in the operation of unmanned aerial systems (UAS). FIXAR EDU is a small copy of the FIXAR 007 flagship, and has two flight modes: copter and airplane. This allows you to gain piloting skills of multi-rotor and airplane-type devices. During the operation of this device, you can study not only the stable flight of the multi-rotor system but also aerodynamics, wing lift, as well as a combination of operating skills of both aerodynamic patterns to achieve better results. The FIXAR EDU device is the basis of our training complex for the operation of drones. The support structure, fuselage, electronics, wings and stabilizer are made of 3D-printed plastic. We also supply files for 3-D printing, which allows you to combine this training material with a course on 3D modeling. FIXAR EDU can be used as a base for participating in a variety of thematic robotics contests.

Training program for the educational and methodological complex

The study of aerodynamics and wing lift as exemplified by FIXAR EDU Studying the features of piloting UASs of the aircraft and multi-rotor type Mastering skills and their combination in controlling a copter and an airplane to achieve the best result Thanks to the presence of 3D-printed elements in the design of the device, it is possible to invent, draw, print and replace ready-made elements with your own ones, and experimentally identify how this will affect the flight of the device, its strength, maintainability and safety. The development of applied creative thinking, engineering and implementation of additional features for this kind of device.


•   Electric motors – 4 pcs.
•   Flight controller unit
•   3D-printed structural elements of the support frame
•   Remote control
•   Propellers, pair – 4 pcs.
•   Hand tool
•   Screwdriver, tweezers
•   Batteries – 2 pcs.
•   Charger
•   Additional set of metal ware
•   Training simulator
•   Files for 3D printing, including editable format
•   User guide
•   Assembly guide
•   Educational materials