Beriev Be-200 Altair 3D Model

Beriev Be-200 Altair civil hydroplane 3D model—accurate aircraft geometry for visualization and rendering. Perfect for aviation scenes, marine transport concepts, and educational presentations, featuring a detailed cockpit, fuselage, and water-running hull. Ready for modern 3D projects.

Beriev Be-200 Altair 3D Model

Overview

Beriev Be-200 Altair is a highly detailed 3D model of the iconic Russian amphibious hydroplane, created for visualization, simulation, training projects, and game/CG production. This civil aircraft version is ideal for realistic maritime/airfield scenes, airport hydro bases, rescue and water-landing sequences, and architectural or industrial presentations. The model features clean geometry and production-ready formatting for smooth import into popular 3D workflows.

Usage patterns

  • 3D visualization & marketing: use in presentations, brochures, and digital product pages.
  • Games & real-time projects: suitable for Unreal Engine scenes and interactive environments.
  • Film, VFX & motion design: integrate into ocean rescues, flight sequences, and environment storytelling.
  • Training & education: helpful for demonstrations involving amphibious operations and water landings.
  • Architectural/industrial scenes: place near docks, harbors, and hydroplane ramps.

File format support

  • Downloadable .MAX (3ds Max)
  • Downloadable .OBJ
  • Downloadable .FBX
  • Downloadable .C4D (Cinema 4D)
  • Downloadable .BLEND (Blender)

Compatible software

Works with major 3D tools including Blender, 3ds Max, Maya, Cinema 4D, Unreal Engine, and other applications that support the included standard formats (OBJ/FBX) and import pipelines.

Tags

  • plane
  • be200
  • airplane
  • aquatic
  • fly
  • beriev
  • altair
  • aircraft
  • hydroplane
  • be
  • 200

License

  • Royalty-Free License.
  • Commercial and editorial use according to site license terms.
  • Redistribution of source files is not allowed.
  • Please review the full license details before using the model in published work.

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