2022年自动化专业外文文献翻译材料 .pdf

Intelligent Control and Automation, 2012, 3, 285-290 doi:10.4236/ica.2012.34033 Published Online November 2012 (http:/www.SciRP.org/journal/ica) Lift System Design of Tail-Sitter Unmanned Aerial Vehicle Dizhou Zhang, Zili Chen, Junwei Lv Optics and Electronic Department Mechanical Engineering College, Shijiazhuang, China Email: oec_ Received June 20,2012; revised August 28, 2012; accepted September 4, 2012ABSTRACT The main advantage of tail-sitter unmanned aerial vehicle (UAV) are introduced. Three design solutions of rotor tail-sitter lift system of UAV have been presented and the respective control strategies and characteristics of three solu-tions are also analyzed in the paper, through the related experiments the design of twin-rotor lift system is verified, and its feasibility is proved. The characteristics and the applying background of the twin-rotor tail-sitter UAV are described in detail. Some useful conclusions of the lift system for tail-sitter UAV are obtained. Keywords: Tail-Sitter UAV; Vertical Take-Off and Landing (VTOL); Rotor; Flight Control 1. Introduction Quadrotor helicopter is a kind of vertical take-off and landing (VTOL) multi-rotor unmanned aerial vehicles (UAV). This kind of helicopter has many characteristics e.g., stable hovering and maneuverable flight in tough environment, its important advantage is load capacity. As these advantages, quadrotor helicopter has many utilities, such as search and rescue, building exploration, security and inspection, etc. especially in dangerous and inacces-sible environments. So the aircraft has been widely used in various fields due to the advantages, such as air trans-port, crop monitoring and military reconnaissance. Con-ventional fixed-wing aircraft can fly at very high flight speed, but must rely on the runway in taking off and landing process. On the contrary, the helicopter can take off vertically out of the shackles of the runway, but its flight speed has been greatly hindered. After the Second World War, some companies in the United States, Can-ada and Europe started to develop a kind of vertical take- off and landing (VTOL) aircraft which has the advan-tages of both fixed-wing aircraft and helicopter, obtain-ing high speed at the same time getting rid of the de-pendence on the runway. VTOL aircraft can take off and land with zero velocity and hover in the air like a helicopter, and fly at high speed horizontally like fixed-wing aircraft 1. The tail- sitter UAV is a kind of superior performance VTOL air-craft due to its flexible handling and does not require complex thrust reversing mechanism. The paper is organized as follows, Section 2 introduce the main advantage of tail-sitter UAV. Three kinds of lift system for tail-sitter UAV are presented and discussed in Section 3; Section 4 describes the twin-rotor tail-sitter UAV in detail; Section 5 concludes the paper. 2. Situation of VTOL Aircraft Research Compared with manned aircraft, the size and required power of the VTOL aircraft are relatively small, and the flight speed is low. Therefore, the power system of the VTOL aircraft mainly applies low-power turbine shaft and piston engine. Power system determines most of the VTOL UAV adopts the rotor. According to the imple-mentation of the power system, the current rotor VTOL aircraft can be divided into two sorts, directional thrust aircraft and convertible thrust aircraft. The typical repre-sentative of the directional thrust aircraft is helicopter. The types of convertible thrust aircraft are tail-sitter, tilt-rotor, tilt-body, tilt-ducted fan, tilt-wing, etc. Tail-sitter UAV vertically takes off to a certain height and turn into the horizontal flight mode. When it lands, it climbs with the nose up, and then reduces the thrust and lands vertically 2. There are many unmanned aerial vehicles which apply this kind lift system, e.g., Golden Eye as shown in Figure 1 . The thrust direction of tail- sitter VTOL UAV is fixed to the vertical direction of airframe. When thrust converting, the direction of thrust and airframe turn over synchronously so that thrust con-vertible mechanism is realized simultaneously. The air-craft is light and simple, in the vertical flight condition; the quality of the airframe is mainly distributed in the vertical direction. The applied point of lift works on the barycenter, so the aircraft is natural stable. In the hori-zontal flight, it is easy to operate the UAV in conven-tional fixed-wing aircraft flight mode. In transition ma-neuver, the direction of the trust turns over synchro-nously with the airframe; and the converting process is Copyright ? 2012 SciRes. ICA名师资料总结 - - -精品资料欢迎下载 - - - - - - - - - - - - - - - - - - 名师精心整理 - - - - - - - 第 1 页，共 6 页 - - - - - - - - - D. Z. ZHANG ET AL .286simplified into the maneuver of the fixed-wing aircraft. 3. Lift System Program of Tail-Sitter UAV The majority of the Tail-Sitter UAV relies on lift gener-ated by rotors for flight. The lift system involves single rotor and two rotors. Changes of the lift in the size and direction will have a direct impact on the flight of the UAV, so the choice of lift system is very important for aircraft 3. Here are three system layout programs of tail-sitter UAVs lift and the control methods of each program in vertical mode, transition maneuver and hori-zontal flight. 3.1. Single-Rotor Tail-Sitter UAV Lift System In the single-rotor lift system, the rotor of the UAV is driven by an electrical motor. It balances the anti-torque of the rotor through the torque generating by four control surfaces which are submerged in the downwash of the propeller. The sketch map and the experimental model are as shown in Figure 2 . During the flight, the UAV control the yaw motion, roll motion and pitch motion through the deflection of the control surface. By adjust-ing the rotors speed and changing the power of the lift, UAV fly up and down and hover in the air. The control scheme is as shown in Table 1. Its lift system is a brush- Figure 1. Golden eye UAV. less motor which is fixed to the top of the airframe. Four control surfaces are installed on four wings, submerged in the downwash of the propeller. In vertical flight and hover state, yaw motion is controlled relying on the clockwise or counterclockwise deflection of the four control surfaces. Pitch motion relies on the parallel de-flection of the two control surfaces in the Y axis. Roll motion relies on the parallel deflection of the two control surfaces in the X axis. For achieving the transition ma-neuver from hover to horizontal flight, the deflection of the control surfaces in the Y axis is regulated by the con-trol law until the vehicle reaches the desired pitch angle. In horizontal flight mode, the thrust of the aircraft is greatly reduced, and flight control is similar to the fixed-wing mode. Air moving over the outer body lift surface provides the lift for horizontal flight. Yaw motion is controlled by the parallel deflection of the two control surfaces in the X axis. Pitch motion relies on the parallel deflection of the two control surfaces in the Y axis; roll motion relies on the clockwise or counterclockwise de-flection of four control surfaces. Figure 2. Single-rotor tail-sitter UAV. Table 1. Control scheme of single-rotor tail-sitter UAV.Vertical Mode Horizontal Mode Yaw Motio Clockwiseor counterclockwise deflection of four control surfacesParallel deflection of the two control surfaces in the X axis Pitch Motion Parallel deflection of the two control surfaces in the Y axis Parallel deflection of the two control surfaces in the Y axis Roll Motion Parallel deflection of the two control surfaces in the X axis Clockwise or counterclockwise deflection of four control surfacesVTOL Increase or decrease the speed of the motor - Copyright ? 2012 SciRes. ICA名师资料总结 - - -精品资料欢迎下载 - - - - - - - - - - - - - - - - - - 名师精心整理 - - - - - - - 第 2 页，共 6 页 - - - - - - - - - D. Z. ZHANG ET AL .287In the single-rotor lift system, the control surfaces need to be adjusted to balance the anti-torque generated by the single-rotor rotation before taking off, in order to avoid unnecessary deflection of the airframe which is harm to the steady flight of the UAV. The two wings on the X axis play the role of balancing the anti-torque in vertical flight, but in horizontal flight, they dont gener-ate lift force, but they greatly increase weight of the body. 3.2. Coaxial Dual-Rotor Tail-Sitter UAV Lift System Coaxial dual-rotor tail-sitter utilizes a propulsion system having a pair of brushless motor in coaxial configuration, which is shown as Figure 3 . It balances the anti-torque of the rotors by the inverse rotating of the two rotors, to stabilize the flight attitude 4. During the flight, the alti-tude of the UAV is controlled by decreasing or increas-ing the combined thrust of the two propellers. The yaw, pitch and roll motion is controlled via rudder and stabi-lizer installed below the two rotors, and the control scheme is shown in Table 2. Figure 3. Coaxial dual-rotor tail-sitter UAV. During the Vertical flight, the vehicle balances the anti-torque precisely by regulating the speed of the two motors to stabilize the flight attitude. Differential veloc-ity of the two motors can control the yaw motion of the aircraft. Pitch motion of this configuration is controlled via the deflection of horizontal stabilizer. To control the roll motion, the aircraft moves the rudder. Converted from the vertical mode to the horizontal flight, the de-flection of horizontal stabilizer is regulated until the UAV reaches the desired angle. During the horizontal mode, the aircraft is airborne and the forward motion is attained-air moving over the outer body wings and pro-vides the lift for horizontal flight. In horizontal flight; the yaw motion is controlled by the rudder which provides the direction of the aircraft. When Pitch motion is changed to horizontal stabilizer motion, Roll motion is controlled by the differential velocity of the two motors and the vehicle thrust is regulated by the velocity of the propulsion system. In coaxial dual-rotor lift system, the two motors are installed in the same axis direction precisely, and the speed difference between the two motors needs to be controlled within an allowable range. There are also higher requirements in the mechanical installation and control Alpha. However, in this lift system, if one motor failure, the aircraft can rely on the other motor to con-tinue the flight through using the rudder to balance the anti-torque generated by the motor.3.3. Twins-Rotor Tail-Sitter UAV Lift System In the twin-rotor tail-sitter UAV Lift System, there are two brushless motors on the top of the airframe 5 as Shown in Figure 4 . The motors rotate inversely to bal-ance the anti-torque of each rotor. Decreasing or in-creasing the combined thrust of the two rotors could con-trol the flight attitude. Two ailerons are installed under the two rotors. Yaw, pitch and roll motion of the aircraft are controlled through the deflection of ailerons and ad-justing the speed of the two motors. In the Vertical flight mode, the UAV balances the anti-torque precisely by regulating the speed of the two motors, to stabilize the flight attitude. Yaw motion is controlled through the Differential deflection of the two ailerons; while to control the pitch motion, two ailerons need to deflect in parallel. Differential velocity of the Table 2. Control scheme of coaxial dual-rotor tail-sitter UAV. VerticalMode Horizontal Mode Yaw Motion Differential velocity of the two motors Rudde Pitch Motion Stabilizer Stabilizer Roll Motion Rudde Differential velocity of the Two motors VTOL Increase or decrease the combined thrust of the two motors- Copyright ? 2012 SciRes. ICA名师资料总结 - - -精品资料欢迎下载 - - - - - - - - - - - - - - - - - - 名师精心整理 - - - - - - - 第 3 页，共 6 页 - - - - - - - - - D. Z. ZHANG ET AL .288two motors can control the roll motion of the aircraft. Decreasing or increasing the combined thrust of the two rotors could control the flight attitude. Converted from the vertical mode to the horizontal flight, the deflection of two ailerons is regulated until the UAV reaches the desired angle. In the horizontal mode, when forward mo-tion of the aircraft is attained-air moving over the outer body wings provides the lift for horizontal flight. During horizontal flight, the yaw motion is controlled by the differential velocity of the two motors. Pitch motion is controlled by the parallel deflection of the two ailerons. Roll motion is controlled through differential deflection of the two ailerons. The vehicle thrust is regulated by the velocity of the propulsion system (See Table 3). In the twin-rotor lift system, two motors need to be in-stalled symmetrically in Z axis direction, and the speed of the two motors are required to controlled precisely, in order to stabilize the aircraft in flight. If one motor fails during the flight, the aircraft cant continue the flight relying on the other motor. Figure 4. Twin-rotor tail-sitter UAV. 4. Twin-Rotor Experimental Model of UAV According to the analysis and comparison of the three kinds of lift system above mentioned. The twin-rotor lift system can provide greater lift power compared with the single-rotor. Meanwhile, compared to the coaxial dual- rotor, the twin-rotor is relatively simple in terms of me-chanical installation .So we finally decide to adopt the twin-rotor lift system to manufacture an experimental UAV model. The well-made twin-rotor tail-sitter UAV is shown in Figure 5. The airframe of the UAV is built of polystyrene foam sheet, and the vehicle is powered by propulsion systems which consists of two brushless motors juxtaposed on the airframe, which drive a pair of propellers of 90 50 in. The motor were driven by two 30A electronic speed con-trollers (ESC), and the power is provided by a Li-Poly battery. At the bottom of the airframe, two ailerons are installed under the downwash of the propellers. The de-flection of the rudders is controlled by two servos, which is used to control the pitch and yaw motion of the aircraft in vertical flight. Parameters of this aircraft are shown in Table 4. An inertial measurement unit (IMU) is placed in the UAV in order to measure the aircraft motion, which con-sists of three-axis digital gyroscope (L3G4200D), three- axis digital accelerometer (ADXL345) and three-axis Figure 5. Well-made twin-rotor experimental UAV model.Table 3. Control scheme of twin-rotor tail-sitter UAV. Vertical Mode Horizontal Mode Yaw Motion Differential deflection of the two ailerons Differential velocity of the two motors Pitch Motion Parallel deflection of the two ailerons Parallel deflection of the two ailerons Roll Motion Differential velocity of the two motors Differential deflection of the two ailerons VTOL Increase or decrease the combined thrust of the two motors - Copyright ? 2012 SciRes. ICA名师资料总结 - - -精品资料欢迎下载 - - - - - - - - - - - - - - - - - - 名师精心整理 - - - - - - - 第