Drone Rack with Horizontal Folding Fuselage Design Developed

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Product Background

The rise of the industrial-grade drone market: Compared to consumer-grade drones, which are mainly used in entertainment and leisure scenarios, industrial-grade drones have developed rapidly due to their diverse application scenarios. According to Frost & Sullivan's prediction, the industrial drones will maintain a high growth rate from 2020 to 2024, and their market size will exceed that of consumer-grade drones for the first time, becoming the main market for civilian drones globally. This has prompted enterprises to develop large-capacity drones to meet the needs of industrial-grade applications, thereby promoting the development of large-capacity drone frames.
Application scenario demand drive: In the field of geological exploration, the traditional methods of carrying equipment on the back of people or by horse or renting manned helicopters are inefficient, costly, and risky. Heavy-duty drones can transport equipment to remote collection points, improving efficiency and reducing costs. In emergency fire and rescue operations, in the face of large-scale disasters in harsh environments outside cities, such as fires and floods, drones are needed to transport supplies and ensure communication. Heavy-duty drones can play an important role. Additionally, in power construction, such as in the mountainous areas of Zhejiang Quzhou, heavy-duty drones have successfully lifted over 500 kilograms of transmission tower materials. These scenarios have placed high demands on the load capacity of drones, driving the development and application of large-capacity drone frames.

Technological advancements provide support: The progress in materials technology is one of the key factors. The application of aerospace-grade composite materials has enabled the frame to maintain structural strength while reducing weight, thereby enhancing the operational capabilities of unmanned aerial vehicles. At the same time, aerodynamic optimization design of rotors, improvements in battery and motor technologies, etc., also contribute to increasing the payload capacity of unmanned aerial vehicles. Moreover, advanced algorithms and control strategies, such as the development of multi-point collaborative control systems, can ensure the stability and safety of multi-machine synchronous operations, providing technical support for the design and application of large-load unmanned aerial vehicle frames.
Low-altitude economic development contributes: The rise of low-altitude economy has gradually revealed the advantages of unmanned aerial vehicles in various fields such as construction, rescue, and post-disaster reconstruction. Large-load unmanned aerial vehicles, as an important component of this, can play a unique role in these fields. With the continuous development of low-altitude economy, the market demand is also increasing, creating a favorable environment for the development of large-load unmanned aerial vehicle frames.

Replacement of traditional transportation methods: Traditional transportation methods such as mule and horse transportation, helicopter transportation, etc., have problems such as low efficiency, high cost, or significant environmental impact. Large heavy-duty drones have the advantages of unmanned operation, large payload, long endurance, environmental friendliness, no need for large airports and taxiing runways, etc. They can to some extent replace traditional transportation methods and meet the transportation needs in specific scenarios, which has also promoted the development of large heavy-duty drone platforms.

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