The 6-degree-of-freedom platform is widely used in various industries, including:
1. Entertainment industry:
-Dynamic Cinema: By controlling the movement of the 6-degree-of-freedom platform, it brings viewers a more realistic and exciting viewing experience. For example, in some 4D or 5D cinemas, the seats are installed on a 6-degree-of-freedom platform, which can perform special effects such as falling, shaking, blowing wind, and rain according to the plot of the film. Coupled with carefully designed smoke, rain, photoelectric, bubble, odor, etc., it creates a fully perceptual environment consistent with the content of the film.
-Sensory game: Players stand or sit on a 6-degree-of-freedom platform, and their body movements can be perceived by the platform and transformed into in-game actions, making the gaming experience more immersive. For example, in racing games, flying games, etc., the platform can simulate the acceleration, braking, turning of vehicles, as well as the takeoff, landing, rolling and other actions of airplanes.
-Theme park amusement facilities: such as roller coasters, jumping machines, and other amusement projects. The 6-degree-of-freedom platform can enhance visitors' sense of excitement and immersion. By precisely controlling the movement of the platform, simulate real movements and thrilling experiences under conditions such as high speed, altitude, sharp turns, and bumps.
2. Simulation training industry:
-Flight simulation: Flight simulators are one of the important application areas of 6-degree-of-freedom platforms. It can accurately simulate various postures and movements of aircraft in the air, including takeoff, landing, cruising, rolling, diving, etc., providing pilots with near real training scenarios, helping them master flight skills, improve their ability to deal with various situations, and ensure flight safety.
-Ship simulation: used to simulate various postures and movements of ships in the ocean, such as navigation, steering, shaking, etc., providing a realistic training environment for ship pilots. This helps to improve the operational skills and coping abilities of pilots in complex sea conditions, ensuring the safe navigation of ships.
-Car driving simulation: It can simulate the driving state of vehicles under different road conditions, such as acceleration, deceleration, turning, braking, bumps, etc., providing drivers with realistic driving training scenarios. By training in simulators, drivers can better master driving skills and improve their awareness of road traffic safety.
-Military training: simulation training applied in the military field, such as tank driving simulation, infantry tactical training, etc. The 6-degree-of-freedom platform can simulate various terrains and motion states in combat scenes, improving soldiers' combat skills and response capabilities.
3. Aerospace field:
-Simulation experiment: used to simulate the performance of aircraft under various extreme conditions, such as high temperature, high pressure, high speed, vibration, etc., providing important experimental data for the development and design of aircraft. For example, simulating the flight state of a spacecraft in the atmosphere, the process of re-entry into the atmosphere, and docking in the space environment.
-Dynamics simulation: helps researchers analyze and understand the dynamic characteristics of aircraft, such as attitude control, orbit control, flight stability, etc., providing theoretical support for the design and optimization of aircraft.
-Aircraft structure testing: Testing the strength, stiffness, fatigue, and other aspects of the aircraft structure to verify its reliability and safety. For example, simulating the force situation of an aircraft during takeoff, landing, and flight, testing the load-bearing capacity and fatigue resistance of the structure.
4. Precision machining industry:
-Six axis linkage machine tool: As a part of the machine tool, the 6-degree-of-freedom platform can achieve precise positioning and machining of workpieces in multiple directions, improving machining efficiency and accuracy. For example, in the machining of complex components such as aircraft engine blades, automotive engine cylinder blocks, etc., a 6-degree-of-freedom platform can enable cutting tools to machine workpieces at different angles and positions.
-Laser welding: During the laser welding process, the 6-degree-of-freedom platform can accurately control the position and posture of the welding head, ensuring the accuracy and quality of the welding. For example, in industries such as automobile manufacturing and electronic equipment manufacturing, laser welding technology is widely used for connecting components, and the application of a 6-degree-of-freedom platform can improve the efficiency and reliability of welding.
5. Medical equipment field:
-Surgical robot: Provides precise positioning and movement functions for surgical robots, enabling doctors to operate surgical instruments more accurately and perform minimally invasive surgeries. For example, in fields such as cardiac surgery and neurosurgery, the 6-degree-of-freedom platform can help doctors achieve more precise surgical operations, reduce surgical trauma and complications.
-Image guided interventional surgery: Under the guidance of imaging equipment, the 6-degree-of-freedom platform can accurately control the position and direction of interventional instruments, improving the success rate and safety of interventional surgery. For example, in surgeries such as angiography and tumor intervention therapy, a 6-degree-of-freedom platform can help doctors accurately deliver instruments such as catheters and stents to the lesion site.
-Precision radiotherapy: During the radiotherapy process, the 6-degree-of-freedom platform can precisely control the position and angle of the radiotherapy equipment, ensuring that the radiation can accurately reach the tumor site while reducing damage to surrounding normal tissues.
6. Scientific research field:
-Materials Mechanics Experiment: It can simulate the deformation, fracture, and other behaviors of materials under different stress conditions, helping researchers study the mechanical properties and failure mechanisms of materials. For example, in research in the fields of building materials, aviation materials, automotive materials, etc., a 6-degree-of-freedom platform can provide experimental conditions for testing the mechanical properties of materials.
-Biomedical research: used to simulate the physiological environment and movement state in living organisms, helping researchers study biomechanical, biomechanical, and other related issues. For example, in the fields of skeletal mechanics, muscle mechanics, cardiovascular mechanics, etc., a 6-degree-of-freedom platform can provide researchers with experimental methods.
-Earthquake simulation: Simulating the ground motion and building response during an earthquake, providing experimental data for earthquake engineering research and seismic design. For example, in the study of seismic performance of building structures, a 6-degree-of-freedom platform can simulate seismic waves of different intensities and frequencies to test the seismic resistance of building structures.
7. Automated production industry: In automated production lines, a 6-degree-of-freedom platform can be used for precise positioning and assembly of components, improving production efficiency and product quality. For example, in the production process of electronic product assembly, automotive component assembly, etc., the 6-degree-of-freedom platform can achieve fast and accurate positioning and installation of components.
8. RF simulation field: The 6-degree-of-freedom antenna adjustment device can simulate the dynamic changes of the antenna on an aerial vehicle, or different installation angles in complex terrain environments, providing accurate antenna position and attitude control for RF simulation and improving the authenticity and accuracy of the simulation.
