登录

Clark Y-14 Wing Performance: Deployment of High-lift Devices (Flaps and Slats)

Overview

Source: David Guo, College of Engineering, Technology, and Aeronautics (CETA), Southern New Hampshire University (SNHU), Manchester, New Hampshire

A wing is the major lift-generating apparatus in an airplane. Wing performance can be further enhanced by deploying high-lift devices, such as flaps (at the trailing edge) and slats (at the leading edge) during takeoff or landing.

In this experiment, a wind tunnel is utilized to generate certain airspeeds, and a Clark Y-14 wing with a flap and slat is used to collect and calculate data, such as the lift, drag and pitching moment coefficient. A Clark Y-14 airfoil is shown in Figure 1 and has a thickness of 14% and is flat on the lower surface from 30% of the chord to the back. Here, wind tunnel testing is used to demonstrate how the aerodynamic performance of a Clark Y-14 wing is affected by high-lift devices, such as flaps and slats.

Figure 1. Clark Y-14 airfoil profile.

Procedure
  1. For this procedure, use an aerodynamics wind tunnel with a test section of 1 ft x 1 ft and a maximum operating airspeed of 140 mph. The wind tunnel must be equipped with a data acquisition system (able to measure angle of attack, normal force, axial force and pitching moment) and a sting balance.
  2. Open the test section, and install the wing on the sting balance. Start with clean wing configuration.
  3. Place a handheld inclinometer on the sting balance, and adjust the pitch angle adjustment knob to set the sting balance

Log in or to access full content. Learn more about your institution’s access to JoVE content here

Results

The results of the clean wing configuration are shown in Table 1. Figures 6 - 8 show all three coefficients vs angle of attack, α, for all four configurations. From Figure 6, both the flap and slat enhanced the lift coefficient, but in different ways. Comparing the clean wing and the slat lift curve, the two curves are almost overlapping at low angles of attack. The clean wing lift curve peaks to about 0.9 at 12°, but the slat curve continues to rise to 1. 4 at 18°. This in

Log in or to access full content. Learn more about your institution’s access to JoVE content here

Application and Summary

Lift generation can be enhanced by the deployment of high-lift devices, such as flaps and slats. Most airplanes are equipped with flaps, and all commercial transport airplanes have both flaps and slats. It is critical to characterize the performance of a wing with flaps and slats during aircraft development.

In this demonstration, a Clark Y-14 wing with a flap and a slat was evaluated in a wind tunnel. The forces and moment measurements were collected to determine the lift, drag and pitching m

Log in or to access full content. Learn more about your institution’s access to JoVE content here

References
  1. John D. Anderson (2017), Fundamentals of Aerodynamics, 6th Edition, ISBN: 978-1-259-12991-9, McGraw-Hill
Tags
Clark Y 14Wing PerformanceHigh lift DevicesFlapsSlatsLift generating ApparatusWing GeometryPressure DifferentialSurface AreaWing Cross SectionAirfoilChord LineCamberPositive CamberWind SpeedTakeoffLandingLeading EdgeTrailing EdgeSlatFlapLift CoefficientDrag Coefficient

跳至...

0:01

Concepts

3:18

Evaluating the Performance of a Clark Y-14 Wing in a Wind Tunnel

6:13

Results

JoVE Logo

政策

使用条款

隐私

科研

教育

关于 JoVE

版权所属 © 2024 MyJoVE 公司版权所有,本公司不涉及任何医疗业务和医疗服务。