Aircraft Design MCQ – Crew Station
1 - Question
Crew station design is affected by?
a) Vision requirements
b) Lift only
c) Weight effects only
d) Drag required only
View Answer
Explanation: Vision requirements are one of the primary factor affecting overall crew station or cockpit design. Lift affects aerodynamics of the aircraft. Weight will affect lift requirements
2 - Question
Which of the following is correct?
a) Vision requirements will be used to determine location of cockpit
b) Crew station design is based on lift only
c) Cockpit design is not affected by visual requirements
d) Weight will be always same as lift
View Answer
Explanation: Unobstructed outside vision will be used to evaluate design of cockpit. Vision requirements will affect the location of cockpit as well. Weight is not always same as lift.
3 - Question
Why some slope is provided at the nose of an aircraft?
a) To provide unobstructed runway vision
b) To provide obstruction to vision
c) Only to increase lift
d) Only to reduce weight
View Answer
Explanation: A cockpit design is highly affected by pilot’s vision requirements. The Pilot must be able to view the runway when they are on final approach. Hence, to provide unobstructed runway vision nose of the a/c must slope away from the eye of pilot.
4 - Question
Which of the following is incorrect?
a) Cockpit is always located directly above the wing
b) Lofting is mathematical model for skin
c) Conceptual design is first phase of the design process
d) Cockpit design is affected by visual requirements of pilot
View Answer
Explanation: Cockpit is not always located at the wing. Lofting is done to provide mathematical model of our aircraft. Conceptual design is the first phase of aircraft design process. In conceptual design we will be dealing with some fundamental principles of design of an aircraft.
5 - Question
Over- side vision requirements prevent locating the cockpit directly above wings.
a) True
b) False
View Answer
Explanation: Over-side vision requirements will not let us to locate the cockpit directly above wings. Location of cockpit is highly influenced by vision requirements. Safety criteria is also used to estimating and placing the cockpit.
6 - Question
Which range of pilot size are used to design a typical military aircraft?
a) Size from 5th to 95th percentile for male pilots
b) Size from 0th to 2nd percentile
c) Size of 3rd percentile always
d) Size doesn’t concern of design
View Answer
Explanation: Typically, cockpit of an aircraft is designed for particular size range of pilot. A typical military aircraft has cockpit design which can accommodate 5th to 95th percentile of male pilots.
7 - Question
Determine approximate value of approach angle if, overnose angle is 20° and approach speed is 100knots.
a) 13°
b) 5°
c) 2°
d) 3°
View Answer
Explanation: Given, overnose angle O = 20°, approach speed V = 200knots. Now, Approach angle A is given by, A = O – 0.07*V = 20 – 0.07*200 = 13°.
8 - Question
Following diagram represents ____
a) typical fighter cockpit
b) typical glider
c) typical empennage
d) wing layout
View Answer
Explanation: A typical fighter cockpit is shown in the diagram. The above diagram is representing a typical cockpit designed for 95th percentile pilot. Glider is type of aircraft. The empennage is tail section of aircraft. Wing layout is based on its planform shape.
9 - Question
Seat reference point is the point where?
a) Seat pan meets the back
b) Pilot head is located
c) Lift is concentrated
d) Weight is carried out in cockpit
View Answer
Explanation: The point at where seat pan meets back is termed as seat reference point. It can be used to define fundamental terms in cockpit design. Legroom requirement, height etc. are using seat reference point as a reference.
10 - Question
Overnose angle is defined based on?
a) Pilot’s eye point
b) Seat reference point
c) Seat length
d) CG of aircraft
View Answer
Explanation: Pilot’s eye point is used to define the overnose angle. Grazing angle, pilot’s head clearance is also defined by using pilot’s eye point. Seat reference point can be used to provide reference to legroom.
11 - Question
Higher seat back angle (>60°) will result in __________
a) improvement to withstand high- g loads
b) drag increment
c) outside vision improvement
d) maximum drag
View Answer
Explanation: Typically, seat back angle can vary from 12° to 40°. However, some more advanced studies consider seat back angle of up to 70-75 degrees. This is much higher seat back angle will improve pilot’s ability to withstand high g turns
12 - Question
Overnose vision angle will be same for all aircrafts.
a) True
b) False
View Answer
Explanation: No, overnose angle is not always same for all aircrafts. Typically, military aircraft requires overnose of 17 degree for transport or bomber aircraft. However, a fighter will have overnose vision of 10-15 degrees.
13 - Question
Which of the following is correct?
a) Overnose angle = approach angle + 0.07*approach speed (in knots)
b) Overnose angle = (approach angle)2 + 7*approach speed (in knots)
c) Overnose angle = (approach angle)2
d) Approach angle = (Overnose angle)2
View Answer
Explanation: Correct relation between overnose angle and approach angle is given by, Overnose angle = approach angle + 0.07*approach speed (in knots). This equation can be used only when initial layout is completed and we know the exact location of pilot’s eye point and main landing gear.
14 - Question
A typical a/c has approach speed of 100 knots. If approach angle is 10° then, estimate value of overnose angle.
a) 17°
b) 25°
c) 10°
d) 40°
View Answer
Explanation: Given, approach speed V=100knots, approach angle a=10°. Now, overnose angle = a+0.07*V = 10 + 0.07*100 = 17°.
15 - Question
What is the grazing angle?
a) Smallest angle between pilot’s line of vision and the cockpit windscreen
b) Same as over nose angle
c) Seat back angle
d) Seat reference angle
View Answer
Explanation: The transparency grazing angle is defined as the smallest angle between pilot’s line of vision and the cockpit windscreen. It is not same as the overnose angle. Seat reference point is defined as the point where seat pan meets back.