gate 2020 solutions
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GATE 2020 SOLUTIONS
AEROSPACE ENGINEERING
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Ans. A
Ans. B
Ans. B
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Ans. C
Ans. A →f(푥 +푥 ) ≥ f(푥 ) + f(푥 )
By hit and trail (easy) -
Let 푥 =2 and 푥 =3
(A). e ≥ + e ...............................possible (B). (2 + 3) ≥ √2 +√3 .....................not possible
(C). 1/ (2+3) ≥ 1/2 +1/3 .......................not possible
(D). 푒 ≥ 푒 + 푒 ................not possible
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Ans. A
Ans. B Angle covered minute hand per minute = 6° (Time reference is 12:00 hours)
Angle covered by hour hand per minute = 0.5°
At 3:15 ⟹ Minute hand will travel 15 minutes and hence covering = 15x6 =90°
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Hour hand could have travelled for 180+15=195 minutes and hence angle covered by hour hand = 0.5 x195 = 97.5°
Angle between 2 hands = 97.5 – 90 = 7.5°
Ans. C → For maximum possible area in the circle, Area = √2a x √2a= 2a²
Required area = Π a²-2a²
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Ans. C a푥 -bx+c = 0
where a, b and c are constants and roots are real and equal.
α+β= b/a ..........1
αβ = c/a ..........2
And we know α = β, so by above equation
β³ = bc/2a²
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Ans. B The average no. of students evolved in school p , X = (3+5+5+6+4)/5=
23/5
The average of the difference of the no. of students enrolled in school p and q, Y = (1+2+3+1+1)/5 = 8/5
So, X/Y = 23/8
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Ans. C f(x) = |x|
f(x) is continuous but ( ) is not defined at
x = 0.
f’(x-h) ≠ f’(x+h)
Ans. D
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f(x) =
√ , 휆 = (x − 휇)
→ For maximum, f’(x) = 0
So, x = 휇
Ans. A y = A푒 +B푒
∵ A, B and m are constants
Roots = -m, m
퐷 -푚 = 0
-푚 y = 0
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Ans. C For water, 휇 =휇°.
So, when T increases → Cohesion decreases → 휇 decreases.
For air, 휇 =휇°+훼푇 − 훽푇
So, when T increases → 휇 increases.
Ans. D No matter how complex is the geometry of the body, the aerodynamic forces and moments acting on the surface of the body moving in the fluid are entirely due to pressure and shear. Hence the net effect of pressure and shear stress integrated over a complete body gives resultant aerodynamic force and moment acting on the body. To calculate coefficients we need extra information regarding freestream velocity and density of the fluid. Hence Options A, B and C are omitted and only Option D is right.
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Note: - Refer Introduction to aerodynamics by John D Anderson chapter 1 section 5 for the derivation of these forces and moments due to pressure and shear acting on the body moving in the fluid.
Ans. C
Velocity of (2) at (1), V = Γ
Π
Velocity of (1) at (2), V = ΓΠ
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So finally vortex will be translate along +Y direction with velocity at the line vortex equal to Γ
Π .
Ans. B The volumetric flow rate per unit depth
Q =휓 - 휓
= 1- (-1) = 2 푚 /푠
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Ans. C Hint: Raleigh flow
Ans. B Airy’s stress function,
∅ = A푥 + B푦 + Cx푦
휎 = ∅ , 휎 = ∅ , 휏 = − ∅
∵ ∇ (휎 + 휎 ) = 0
∴ ∅ + 2 ∅ + ∅ = 0
So, A + B = 0
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Ans. D For Plan strain field,
휀 = A푦 + x
휀 = A푥 + y
훾 = Bxy + y
Compatibility condition
= +
So, B = 4A
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Ans. A For hyperbolic trajectory, e > 1
Orbital energy, 훽 = T + ∅
훽= m푣 -
e = 1 + , Here 훽푖푠positive
m푣 >
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Ans. A For positive훿푟, yawing moment will be negative.
퐶푛 < 0
For positive훿푟, rolling moment will be positive.
퐶 > 0
Ans. C → Stagnation pressure is always increases across the impeller of a centrifugal compressor.
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Ans. B
Ans. C We have total thrust equation from the thermodynamic cycle analysis of aircraft engine as given below
퐹 = 푚̇ (1 + 푓)푐 − 푐 + (푝 − 푝 )퐴 For the optimum expansion entire thrust is from the nozzle expansion and there will be no pressure thrust, hence only condition to obtain this thrust is omitting pressure thrust. i.e.
(푝 − 푝 )퐴 = 0 This gives
푝 = 푝 Exit pressure of the nozzle is same as ambient pressure. (Option C)
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Ans. D The yield stress does not depend on length or cross section.
Ans. C
Aerodynamics loads passes through aerodynamic center which lies at ¼ of chord length for symmetrical aerofoil and for steady pullout at largest angle of attack, lift is upward. At location III moments created by Lift will be highest and on bottom there
will tension.
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Ans. A
Natural frequency, 휔 =
→ 휔 ∝1퐿
→ 푆표,휔 =휔/4
Ans. B A = sin휃 tan휃
0 cos휃
휆 + 휆 = sin휃 + cos휃
휆 . 휆 = sin휃 . cos휃
→ 휆 + 휆 = (휆 + 휆 ) - 2휆 .휆 = 1
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Ans. 13.45 km/s 푉 = 13.5 Km/s; theta = 5 degrees
푉 = 푉 × cos휃 = 13.5× cos 5 = 13.45 Km/s
Ans. −ퟓ.ퟓퟔ°
→ [푢 푣 푤] ≡ [100 −10 20]
V = (푢 + 푣 + 푤 ) = 102.46 m/s
푣 = Vsin훽
훽= −5.56°
Ans. 2 Reference for similarity solutions to diffusion equation can be found in
1) Incompressible flow by R.L Panton 2) Fluid mechanics by Pijush K Kundu and M.Cohen
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Ans. 29.85 K 퐶푡 = 0, 퐶푡 = 150 m/s, U = 200 m/s
W = U. [퐶푡 -퐶푡 ] = 200*150 J/kg
∵ Δℎ = W
Cp.Δ푇 = W = 200*150
Δ푇 = ∗ = 29.85 K
Ans. 0.01 rad/m T = 3.2 kN-m, G = 25GPa
∵ = =
∵ J = ∫
(for a closed section)
J = 0.0128X10
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= = 0.01 rad/m
Ans. 3.55 m = 5000 kg, v = 360 km/h = 100m/s
R = 400 m
∵ R = ( )
So, n = 3.55
Ans. C
x + y = c
xdx +(y-c)dy = 0
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+ ( ) = k
푥 + (y − c) = k → Circle
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Ans. D
From the detailed figure given above, it is clear that intersection points for 푌 and 푌 lines are little offset from points푋 ,푋 &푋 , also flow direction changes only after encountering the shock wave, then remains parallel to the wall. Hence option A and
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option B are straight away omitted. We know that across oblique shock wave static pressure increases and stagnation pressure decreases. Whereas in expansion waves stagnation properties unchanged but static pressure decreases in gradual manner (Note: - this is not sharp change in Prandtl Mayer expansion fan). Now option C also omitted because it doesn’t satisfy gradual change across expansion wave. So only option satisfies both physics as well as geometry of the flow is Option D.
Ans. D
K = E/3(1-2휇), G = E/2(1+휇)
→ K = G (Given)
3(1-2휇) = 2(1+휇)
3 – 6. 휇 = 2 + 2.휇
휇 = 1/8
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Ans. C
→ Part AC, here BC is rigid
훿 = = . =
→ Part BC, Here at point C is load of N and moment of 3×2 N-m due to AC bar.
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훿 = ..
+ . ..
=
휃 = ..
+ . ..
=
→ 훿 = 훿 + 휃 .2
= + =
→ 훿 = 훿 + 훿
= + =
Ans. D
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→ 훾 = 2휖
So, A = 1
B = 2(1+휐)
C = -휐
⟹ C = A -
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Ans. C
For directional static stability, > 0
a/p A B C
Yawing
moment
푑퐶푑훽 > 0
(stable)
푑퐶푑훽 > 0
(stable)
푑퐶푑훽 < 0
(unstable)
Aero plane A is more stable than aero plane B.
Ans. A
x= a cos휃 , y = b sin휃
a = 7m, b = 5m, 휋 = 22/7
→ sin휃 + cos휃 = + = 1 → ellipse
Area = 휋푎푏 = ×7× 5 = 110 m
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Ans. B
= Const.
→ V ∝ N
→ N ∝ 푇푇
→ = =
So, 푁 = 14491 rpm
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Ans. B
휎 = 18 MPa, 휎 = 12MPa, 휏 = 4 MPa
→ 휎 = + .cos 2휃 + 휏 sin 2휃 .......... (1)
→ 휎 = - .sin 2휃 + 휏 cos 2휃 ...................... (2)
→ 휎 + 휎 = 휎 + 휎 ..................................... (3)
For Maximum shear stress, by eq. (2)
tan 2휃 = - = - ∗
휃 = - 18.43°
So 휎 = 15 MPa, 휎 = 15 MPa and 휎 = 5 MPa
Ans. 1
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AX = B
1/√2 0 1/√20 1 0
1/√2 0 −1/√2.푥푦푧
= 01
−√2
So,
x = -z .......... (1)
y = 1 .............. (2)
x – z = -2 ....... (3)
By above three equations,
x = 1, y = and z = -1
→ x + y + z = 1
Ans. 0.0104
→Analytical method,
∫ (푥 − 2푥 + 1)푑푥 = − 2. + 푥 = = 0.33
→ Numerically trapezoidal method,
f(x) = 푥 − 2푥 + 1
h = = 0.25
푦 푦 푦 푦 푦
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x 0 0.25 0.5 0.75 1
f(x) 1 0.5625 0.25 0.065 0
∫ (푥 − 2푥 + 1)푑푥 = [(푦 + 푦 ) + 2. (푦 + 푦 + 푦 )] = 0.3437
→ Numerical – Analytical = 0.0104
Ans. 0.93125
→ 퐶 = ( ).훼. + 퐶
∵ = 0.01075
퐶 = 0.01075× 훼 + 0.1
At 훼 = 6∘
퐶 = 0.01075× 6 + 0.1 = 0.745
퐶 at compressible flow(M = 0.6),
퐶 = ,
√ = .
√ . = 0.93125
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Ans. 0.00997
The static pressure is same at section A and B. (0.995푈 )
So, ∆p = 0
→ Drag = 푚표푚푒푛푡푢푚|inlet - 푚표푚푒푛푡푢푚|outlet
D = 휌A푈 – [휌(퐴− 퐶)푈∞ + 휌퐶(0.995푈 ) ]
= 0.0099휌c푈
퐶 = = 0.00997
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Ans. 2
휃 = 5.75°
∅ = 35°
→ 퐭퐚퐧휽 = 2퐜퐨퐭휷( 푴ퟏퟐ .퐬퐢퐧 휷ퟐ ퟏ
푴ퟏퟐ(휸 퐜퐨퐬 ퟐ휷) ퟐ
)
0.1 = 2×1.428( × .( . )
)
푀 = 2
Ans. 4.11 mm
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→∞ = (linear velocity profile)
훿∗ = ∫ (1−∞
).dy
= 푦 −.
= 훿 - =
→ 훿∗ = .
훿∗| At x=0.5 = . × .× .
. ×
= 4.11
Ans. 1.33°
b = 15m, e = 1, L = 80 KN, 푉∞ = 90 m/s, 휌 = 1.2 Kg/푚
→ 퐿 = 휌∞.푉∞. Γ . .휋
80x1000 = 1.2x90xΓ x .x휋
Γ = 62.87 푚 /s
훼 = Γ
∞ = . = 0.02328 rad = 0.02328*57.3 = 1.33°
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Ans. 3.56 cm
휎 = 280 MPa, T = 10 KN-m
휏 = = 140 MPa
휏 = . = 휏 (Tresca –failure theory)
d = . = 71.38 mm
r = d/2 = 35.67 mm = 3.56 cm
Ans. 0.017
푉 = ( )( )
, 푉 = ( )( )
→ = = 1.0339
→e = 0.01
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Ans. 55.33 m/s
Phugoid mode,
휆 , = -0.02 ± I 0.25
→ 휔 = √2 .
푠 - (휆 휆 ).S +휆 .휆 = 0
푠 + 0.04 S + ( 0.02 + 0.25 ) = 0
푠 + 0.04S+ 0.0629 = 0
휔 = √0.0629 = 0.2507
푉 = √2. . = 55.33 m/s
Ans. 25.64 %
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휂 = 0.95, 푉 = 0.453, = 0.35,
퐶 = 4.8 푟푎푑 =푎 , 퐶 = 4.4 푟푎푑 = 푎
→ = + . (1 - ).휂. 푉
= 0 + ... (1-0.35)× 0.95× 0.453
= 0.2564
= 25.64 % of the chord
Ans. 150 m/s
A single engine propeller driven a/c –
At SL, 휌∞= 1.225 kg/푚
→ 퐶 = 0.025 + 0.049퐶 , w/s = 9844 N/푚
→ R = . .푙푛
→ For maximum range, ( ) should be maximum
∴ 퐶 = 퐶 = K퐶
퐶 =
= 0.714
퐶 = 2퐶 = 0.05
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→ V = = ∗. ∗ .
= 150 m/s
Ans. 1717 m/s
Ideal Ramjet engine,
→ 푀 = 푀 = 2.8, 푇 = 2400K, 훾 = 1.4, R = 287 J/Kg.K
= 1 + .푀 = 2.56
푇 = 937.5 K, ∵ 푇 = 288.16 K
→ 푉 = 푀 . 훾푅푇 = 2.8.√1.4 ∗ 287 ∗ 288.16 = 952.75 m/s
→ 푉 = × 푉 = ..
× 952.75 = 1717 m/s
Ans. 91.65 %
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→ ℎ = ℎ +휂 . .LHV.푚
115.42 = 28.94 +휂 ...32
휂 = 0.9165 = 91.65 %
Ans. 88.21 %
훾 = 1.33
→ 휂 = ′ = ′
→ ′ = = ..
= 0.754
→ = 0.783
→ 휂 = ..
= 0.8821 = 88.21 %
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Ans. 27.07 KN
At SL, 퐼 = 210 s, 퐴 = 0.005푚 , C* = 1900 m/s, 푃 = 50 bar
푃 .퐴 =푚̇ .c* ................ (1)
퐼 = .̇
= ................ (2)
By equation (1),
푚̇ = × × . = 13.157 Kg/s
By equation (2),
C = 2058 m/s
→ F = 푚̇ . 퐶 = 27.07 KN
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Ans. 1.44
∵ 휉 = = √
→ For critical damping, ∵ 휉= 1= √
= 1
C = 2 푚푘 ……….. (1)
→ For over damped, 휉= 1.2= √
C = 1.2 ∗ 2 푚푘 ……….. (2)
→ ( )( )
, = .
.
= 1.44
Ans. 0.62
→ For mass 푀 ,
푋 ′ + 푋" = 2 cm
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→ For mass 푀 ,
푋 ′ + 푋" = 1.24 cm
→ 푥 = 푋 ′ cos(휔 푡) + 푋" cos(휔 푡)
→ 푥 = 푋 ′ cos(휔 푡) + 푋" cos(휔 푡)
∵ Here 푋" and 푋" are negligible.
So, 푋 ′ = 2 cm and 푋 ′ = 1.24 cm
∅ = ′
′ = .
= .
Ans. 3.75 N
→ Due to UDL, 푌 =
→ Due to point load, 푌 = =
So, 푌 - 푌 = - = 0
R = . = . . = 3.75 N
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Ans. 63.02 m/s
Given,
m = 4000kg, S = 25푚 , 퐶 , at SL = 1.65, 휌 = 1.225 kg/푚 ,
g = 9.8 m/푚
→ FOS = 1.25, n = 3.2
→ L = nW ........................................... (1)
→ 휌푉 S퐶 = 푛 W.............. (2)
→ FOS = ................................ (3)
By equations (2) and (3),
푉 =
= × . × × .. × × . × .
= 63.02 m/s
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Ans. 59.93 m/s
Aero plane at SL,
푃∞ = 1.01bar, 푇∞ = 288.16 K, 휌∞ = 1.225Kg/푚 , g = 9.8 m/푠
R = 287 J/kg.K
Aero plane at 3 Km measures pressure 푃 = 0.72 bar and outside temperature T=268.6 K
dT/dh = a; a=lapse rate= -6.5 k/km
(T-Tsea-level)/ (h-0) = -6.5 k/km ⇒ (T-288.16)/(3-0) = -6.5 ⇒ T= 268.66 k
P/Psea-level = (T/Tsea-level) -(g/a*R)⇒ P/1.01 = (268.66/288.16)5.2586⇒ P =0.698 bar
→ 휌푉 = 휌∞푉∞
→ 푉∞= ( )
∞ = ( . . )
. ∗ 10 = 59.93 m/s
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Team GATE Aerospace Engineering (AE):-
Name of Faculty Alma Institute Subject Expertise
Mr Dinesh Kumar IIT Madras Aero Structures and Mechanical Vibration
Mr S Kumar IIT-Mumbai Aero Dynamics, Gas Dynamics
Mr Navaneetha IIST- Trivendrum
Flight Mechanics
Mr Y Krishnan IIT- Kgp Flight Mechanics and Space Dynamics
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