Abstract
An accurate description of the transition corridor is of great significance for the flight process of the vertical take-off and landing (VTOL) fixed-wing unmanned aerial vehicle (UAV). To study the transition flight process of vertical take-off and landing fixed-wing UAVs, the dynamic model and transition corridor model of this type of UAV are established in the current article. The method for establishing the model is based on a reasonable match of the power and aerodynamic force of this type of UAV. From the perspective of flight dynamics, the ducted lift-increasing system’s deflection angle–speed envelope is studied with the maximum lift coefficient of the wing and the system’s available power. The influence of the overall parameters and energy parameters of the UAV on the deflection angle–speed envelope of the ducted lift-increasing system is analyzed, and a method is proposed to expand the vertical take-off and landing fixed-wing UAV’s transition corridor. Taking the UAV as the object, using the established model, the transition flight corridor of the UAV is obtained, the influence of the control parameters on the transition flight is studied, and the appropriate transition flight control strategy is determined. At the same time, the influence of the overall parameters and energy parameters on the transition corridor is calculated. According to the calculation results, the effect of expanding the flight corridor of the UAV is more obvious when increasing the available power than when increasing the aerodynamic parameters by the same proportion.
Highlights
The vertical take-off and landing fixed-wing unmanned aerial vehicle (UAV) can achieve zero-speed take-off and landing without the need for a runway as in the case of the conventional aircraft
There is little work on the transition corridor of vertical take-off and landing fixed-wing UAVs powered by ducts and lift fans
Based on the matching of UAV power and aerodynamic balance, a vertical take-off and landing fixed-wing UAV transition flight corridor is established from the perspective of flight dynamics
Summary
The vertical take-off and landing fixed-wing UAV can achieve zero-speed take-off and landing without the need for a runway as in the case of the conventional aircraft. A ducted vertical take-off and landing fixed-wing UAV scheme is proposed. There is little work on the transition corridor of vertical take-off and landing fixed-wing UAVs powered by ducts and lift fans. The UAV of this configuration can achieve vertical take-off and landing, as well as the high speed and long endurance of the fixed-wing aircraft. Based on the matching of UAV power and aerodynamic balance, a vertical take-off and landing fixed-wing UAV transition flight corridor is established from the perspective of flight dynamics. UAV flight dynamics equation, and u represents the control quantities of the vertical takeowffhaernedylarenpdriensgenfitxseadll-wofinthgeUstAaVte,qaunadntthiteieysaorfetdheefvineertdicaasl take-off and landing fixed-wing. UAV flight dynamics equation, and u represents the control quantities of the vertical take-off and landing fixed-wing UyA=V[,ua,nvd, wth, epy, qa,rre, θd,eφfi,nψe]d as (2). The above Formulas (4), (5) and (7) are the dynamic model of the vertical take-off and landing fixed-wing UAV
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