Wat het doet
A sweeping robot that integrates intelligence, humanity, environmental protection and energy saving to meet the diverse needs of modern families for floor cleaning.
Je inspriatie
Drone Inspiration: Drones have flexible flight capabilities and efficient navigation systems. They can fly accurately and avoid obstacles in the air through the satellite positioning system (GPS) and a variety of sensors (such as air pressure sensors, visual sensors, etc.). In addition, the propeller structure of the drone can generate strong airflow for stable flight and load carrying.
Hoe het werkt
Start: The user starts the robot through a button or mobile phone application. Initialization: After the robot starts, the navigation system starts working and the sensors start scanning the surrounding environment. Path planning: The robot builds a map and plans the cleaning path through the SLAM algorithm. Cleaning: The robot moves along the planned path, and the cleaning system starts working, vacuuming, sweeping or mopping the floor. Obstacle avoidance: During the cleaning process, the robot detects obstacles through sensors and avoids them. Charging: When the battery is low, the robot automatically returns to the charging station to charge. Completion: After cleaning, the robot returns to the charging station to standby or enters sleep mode.
Ontwerpproces
Functional module division: The sweeping robot is divided into main modules such as mechanical structure, sensor system, control system, drive system, cleaning system and power system. Technical selection: Select appropriate sensors (such as lidar, infrared sensor, visual sensor, etc.), motors, microcontrollers and other key components according to needs. Mechanical structure design Appearance design: Design the appearance of the robot, usually round or square, to facilitate free movement indoors. The shell is made of high-strength plastic or metal, with good wear and impact resistance. Walking mechanism design: Design drive wheels and universal wheels to ensure that the robot can travel stably on different ground materials. Cleaning mechanism design: Design side brushes, roller brushes and dust suction ports to improve cleaning efficiency. Dust box design: Design a detachable dust box to facilitate user cleaning and replacement. Sensor system design Collision sensor, infrared sensor, ultrasonic sensor, cliff sensor, gyroscope and accelerometer, Visual sensor
Hoe onderscheidend is het?
Intelligent navigation and obstacle avoidance: It can perceive the environment and build maps in real time, realize autonomous navigation and path planning, and accurately avoid obstacles. Intelligent identification and precise cleaning: It can identify different types of floors and stains, automatically adjust the cleaning intensity and mode, and achieve precise cleaning. Remote control and intelligent interaction: Users can remotely control the robot through mobile phone APP or voice assistant, grasp the cleaning progress in real time, and adjust the mode. Self-cleaning and battery life: Some high-end models have self-cleaning function, which can automatically clean the dust box and filter, and have strong battery life. Multi-function integration: It integrates vacuuming, mopping, and self-cleaning to meet the cleaning needs of different users
Toekomstplannen
Technology upgrade and innovation
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