Lecture with Numerical Examples of Ramjet, Pulsejet and Scramjet
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1 Lecture 41 1
2 Lecture with Numerical Examples of Ramjet, Pulsejet and Scramjet 2
3 Problem-1 Ramjet A ramjet is flying at Mach at an altitude km altitude (Pa = kpa, Ta= C = K., sonic speed, a = 295 m/s). The flow is assumed to enter the intake of the ramjet through a normal shock standing at the intake face. No pre-entry loss or friction loss inside the engine is assumed to exist. Combustion delivery temperature is 1280 K. and the fuel air ratio is 1:40. The area at the intake face is A 1 = m 2 and at the Combustion chamber, A 3 = m 2 3
4 Calculate : i) Mass flow rate through the engine ii) Throat area in the nozzle, A 5 iii) Combustion related pressure drop in the combustion chamber iv) If the nozzle expands to ambient pressure find the thrust produced v) If the nozzle expands only in a convergent nozzle find the thrust produced vi) Calculate the propulsive efficiencies for (iv) and (v) vii) Calculate TSFC in both the cases viii) Complete and draw the cycles for the cases (a) with C-D nozzle and (b) Convergent nozzle 4
5 Solution : Flight velocity=intake velocity of air=m 1.a=536 m/s From isentropic relations, Total temperature at entry, T 0a = 360 K Total Pressure at entry, P 0a = kpa Ambient air density, ρ 1 = P a /R.T a = kg/m 3 Mass flow through the Intake = ρ 1.V a.a 1 =7.3 kg/s Normal shock : From shock tables : At intake face, for M 1 =1.82, M 2 =0.612, T 2 = 334.8K P 02 =0.803.P 01 = kpa, T 02 =T 01 =360 K Since the duct losses due to friction etc are zero, P 03 =P 02 = kpa, T 03 =T 02 = 360 K 5
6 Using isentropic tables, at stn 2 behind the shock, M 2 = , the area may be computed from A 2 /A I = ; Then, A cc /A I = (A cc /A 2 ).(A 2 /A I ) = 2 x =2.33 Inside the combustion chamber, the Mach number may be computed from isentropic tables or relations as : M 3 = 0.26 Combustion chamber calculations : Due to accompanying heat addition, Rayleigh flow tables or relations need to be utilized for calculation of parametric variations. 6
7 Flow in the C-D nozzle may be assessed as : Starting from Mach 0.83 (CC delivery) assuming isentropic flow, A 4 /A t =1.027 in the convergent duct The exit area may be calculated from A t =A 4 /(A 4 /A t )=0.1858/ =0.181 m 2 As no duct loss is prescribed, P 0t =P 04, P t =0.25xP 04 At the exit, after flow through the divergent duct, M e =1.55 ; A t /A e =1.211, T e /T 0e =0.675 Ae=1.211x0.181=0.22 m 2, P e = P a as prescribed From T 0t =T 0e =T 04, as no heat / work is transacted Since, T 0t =T 0e =T 04 =1280 K, then T e = K Jet Vel is now calculated V e = M e γ.r.t e =916.5 m/s For fuel-air ratio of 1:40 thrust is calculated as : 7
8 Flow in the C-D nozzle may be assessed as : Starting from Mach 0.83 (CC delivery) assuming isentropic flow, A 4 /A t = The exit area may be calculated from A t =A 4 /(A 4 /A t )=0.1858/ =0.181 m 2 As no duct loss is prescribed, P 0t =P 04, P t =0.25xP 04 At the exit, M e =1.55 ; A t /A e =1.211, T e /T 0e =0.675 Ae=1.211x0.181=0.22 m 2 From T 0t =T 04, as no heat / work is transacted Since, T 0t =T 04 =1280 K, then T e = K Jet Vel is now calculated V e = M e γ.r.t e =916.5 m/s For a fuel-air ratio of 1:40 the thrust may now be calculated as : 8
9 Thrust is given by : F = ṁ[(1+f)v e -V 1 ]+ A e. (P e - P a ) C-D nozzle Thrust is, F = 4090 N Propulsive Efficiency, η p =F.V a /F.V a +½.ṁ.[(1+f)V e2 - V a2 ] = 51.2 % For fuel-air ratio prescribed as f = 1/40 Sp. Fuel Consn., TSFC = f/(f/ṁ)=0.16 kg/n-hr If the nozzle is only a convergent nozzle: The exit face is the throat of the nozzle. 9
10 convergent nozzle Pressure ratio necessary for choking : Available pr. ratio across the nozzle= P 04 /P a =3.96 The nozzle is choked, and exit pressure, P e =19.1 kpa T e =T t = T 04 /[(γ+1)/2]=1280/1.2 = 1067 K Exit jet velocity, V e =V t = γ.r.t e = 654 m/s From isentropic tables, exit (throat) area, A 4 /A t =1.027 Whence, exit area A e = m 2 Thrust F = ṁ[(1+f)v e -V 1 ]+ A e. (P e - P a ) = 3587 N Sp. Fuel Consn., TSFC = f/(f/ṁ)= N Prop Efficiency η p =F.V a /F.V a + ½.ṁ.[(1+f)V e2 -V a2 ]=54.8% 10
11 Problem 2 Pulsejet Lect 41 An aircraft powered by a pulsejet engine is flying at 12 km altitude, at Mach 2. The engine parameters are given as : inlet area = m 2. Combustion chamber pressure development, P 03 /P 02 = 9.0, heating value of fuel, Q = 43,000 kj/kg, combustion efficiency = Assuming ideal (no loss) flow through the intake, find: (i) The air mass flow rate, (iii) fuel-air ratio, f (v) Thrust of the engine (ii) Maximum Temp. (iv) Exit velocity, V e (vi) TSFC 11
12 At 12 km P 0a = kpa ; T 0a = K The flight velocity is : V a = M a γ.r.t a =590 m/s The air mass flow rate is : = ρ a.v a.a 1 = 15 kg/s Total temp across the intake diffuser remains constant, T 01 =T oa = T a [1+(γ-1)M 2 /2]= 390 K=T 02 Total pressure, P 01 =P oa =P a (T 01 /T 0a ) γ/(γ-1) =147 kpa In the combustion chamber pressure rises from P 02 to P 03 by a prescribed ratio 9.0, and the temp ratio (temp change across the CC) is same by gas laws. The combustion delivery temp is : T 03 =3510 K 112
13 The fuel air ratio may be calculated f =ṁ f /ṁ a =(c p-gas.t 03 - c p-air.t 02 )/Q.η cc = In the jet pipe: The exhaust velocity is V e = 2.c p-gas.t 03.[1-1/ ] = 2297 m/s Specific Thrust, F/ṁ a =(1+f)V e -V a = N-s/kg The thrust. F = N = kn The TSFC = f/(f/ṁ a ) = 50 mg/n-s = kg/n-hr Propulsive Efficiency η p =F.V a /F.V a +½.ṁ.[(1+f)V e2 -V a2 ] =0.418 = 41.8% 13
14 Problem 3 Scramjet A scramjet powered aircraft flys at Mach 5 at km where Ta= K and Pa=9.122 kpa. The intake has a shock structure of two oblique shocks with both deflection angles δ =10 0. By burning hydrogen fuel (Q=120,900 kj/kg), the temp is raised to 2000 K. The fuel air ratio = The nozzle expansion ratio is A 5 /A 4 = 5.0. The inlet and the exit areas are A 1 =A 5 = 0.2 m 2. If c p = 1.51 kj/kg.k ; η cc = 0.8 Calculate : i) Mach number at combustion chamber inlet ii) Exhaust jet velocity iii) Overall efficiency 14
15 Flight velocity is : V a = M a γ.r.t a =1475 m/s Mass flow through the engine ṁ a = ρ a.v a.a 1 =43.3 kg/s Inlet total temp T 01 =T oa =T a [1+(γ-1)M 2 /2]=1300K=T 02 From shock relations or tables, Across the first shock, for M 1 =5 & δ =10 o Shock angle, β =19.4 o. M 2 =4.0 and T 2 /T 1 =1.429 Across the second shock, M 1 =4 & δ =10 o Shock angle, β =22.2 o. M 3 =3.3 and T 3 /T 2 =1.33 In the combustion chamber heat is added to air flow with supersonic speed 15
16 Using Rayleigh Flow relations (or tables) M 4 =1.26, and P 04 /P 0I = 1.033, T 04 /T 0I =0.966 Combustion chamber pressure ratio, P 04 /P 03 =0.228 Fuel-air ratio, f =ṁ f /ṁ a =(c p-gas.t 03 - c p-air.t 02 )/Q.η cc = Nozzle Flow For M 4 =1.26, T 04 /T 4 =1.317, critical area ratio= 1.05 Whence, A e /A t = (A e /A 4 ).(A 4 /A t )=5x1.05 =
17 Nozzle Flow Nozzle outlet Mach number, M e =3.23, for which isentropic temp ratio T 05 /T 5 = 3.11 T 5 = T. T T. T T. T T. T 3. T. T 2. T. T 1 T 1 = K The exhaust velocity, V e = M 5 γ.r.t e = 1560 m/s Specific Thrust, F/ṁ a =(1+f)V e -V a =102 N-s/kg TSFC = mg/n-s = kg/n-hr Thrust, F =43.3 x 102 = 4416 N Propulsive Efficiency η p =F.V a /F.V a +½.ṁ.[(1+f)V e2 -V a2 ] =0.527 or 52.7% 17
18 Ramjet (C-D noz) Comparison of Rotor-less Jet Engines M H km V e m/s F (kn) TSFC Kg/nhr η pr F/ṁ a N/Kg /s Pulsejet Scramjet
19 Next Concluding Lecture 19
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