There are 4 forces acting on the aircraft (Weight, Thrust, Lift, Drag). Assuming that they are all approximately perpendicular to eachother at points AB,C, calculate the following A Calculate the Lift Forces at points A, B, Cif the aircraft was at a constant speed of 350km/h throughout the maneuver. B. Calculate the Lift Forces at points A, B, Cif the aircraft starts the maneuver at point A at a speed of 400km/h, but reduces its speed with constant acceleration so that the pilot feels weightless at point C. C. A human can withstand a maximum of 9 times the gravitational acceleration, ie. if the earth's gravity was more than 9 times what it is now, we would not survive. What is the maximum speed the pilot can enter this maneuver?

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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Question 2: Consider the 5000kg aircraft below being in a 1000m radius looping maneuver (Fig.2).
There are 4 forces acting on the aircraft (Weight, Thrust, Lift, Drag). Assuming that they are all
approximately perpendicular to eachother at points A,B,C, calculate the following:
A. Calculate the Lift Forces at points A, B, C if the aircraft was at a constant speed of 350km/h
throughout the maneuver.
B. Calculate the Lift Forces at points A, B, C if the aircraft starts the maneuver at point A at a
speed of 400km/h, but reduces its speed with constant acceleration so that the pilot feels
weightless at point C.
C. A human can withstand
earth's gravity was more than 9 times what it is now, we would not survive. What is the
maximum of 9 times the gravitational acceleration, i.e. if the
maximum speed the pilot can enter this maneuver?
Figure 2: Looping Aircraft
Transcribed Image Text:Question 2: Consider the 5000kg aircraft below being in a 1000m radius looping maneuver (Fig.2). There are 4 forces acting on the aircraft (Weight, Thrust, Lift, Drag). Assuming that they are all approximately perpendicular to eachother at points A,B,C, calculate the following: A. Calculate the Lift Forces at points A, B, C if the aircraft was at a constant speed of 350km/h throughout the maneuver. B. Calculate the Lift Forces at points A, B, C if the aircraft starts the maneuver at point A at a speed of 400km/h, but reduces its speed with constant acceleration so that the pilot feels weightless at point C. C. A human can withstand earth's gravity was more than 9 times what it is now, we would not survive. What is the maximum of 9 times the gravitational acceleration, i.e. if the maximum speed the pilot can enter this maneuver? Figure 2: Looping Aircraft
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