Respuesta :
Answer:
a) 5.22 m/s
b) 31.4 %
Explanation:
f = rotating speed = 15 rpm = 15/60 =0.25 rps
m = Mass flow rate of air = 42000 kg/s
v = Tip velocity = 250 km/h = 250/3.6 = 69.44 m/s
W = Work output = 180 kW
A = Swept area of wind turbine
r = Radius of wind turbine
η = Efficiency
[tex]r=\frac{v}{2\pi f}\\\Rightarrow r=\frac{250\div 3.6}{2\pi 0.25}=\frac{250}{1.8\pi}[/tex]
[tex]A=\pi r^2\\\Rightarrow A=\pi\left(\frac{250}{1.8\pi}\right)^2\\\Rightarrow A=\left(\frac{250}{1.8}\right)^2\frac{1}{\pi}[/tex]
[tex]m=\rho V\\\Rightarrow m=\rho vA\\\Rightarrow v=\frac{m}{\rho A}\\\Rightarrow v=\frac{42000}{1.31 \left(\frac{250}{1.8}\right)^2\frac{1}{\pi}}\\\Rightarrow v=5.22\ m/s[/tex]
∴ The average velocity of the air is 5.22 m/s
[tex]E=m\frac{v^2}{2}=42000\frac{5.22^2}{2}\\\Rightarrow E=572538.92[/tex]
[tex]\eta=\frac{W}{E}=\frac{180000}{572538.92}\\\Rightarrow \eta =0.314[/tex]
∴ Conversion efficiency of the turbine is 0.314 or 31.4 %
Answer:
(a) 5.223 m/s
(b) 0.314
Explanation:
The mass flow rate (m⁺) of the turbine is related to the density of air(ρ), velocity of air (vₐ) and the cross-sectional area (A) of the turbine as follows;
m⁺ = ρ x vₐ x A -----------------(i)
But;
A = π x r²
Substitute A = π x r² into equation (i) as follows;
m⁺ = ρ x vₐ x π x r² --------------------(ii)
But;
The radius (r) of the turbine is the ratio of the velocity (vₓ) of the turbine to the angular velocity (ω) of its blades. i.e
r = vₓ / ω
Where;
ω = 2 π f [f = frequency i.e number of oscillations/revolutions per second of the blades of the turbine]
=> r = vₓ / (2 π f )
Substitute the value r = vₓ / (2 π f ) into equation (ii) as follows;
m⁺ = ρ x vₐ x π x [vₓ / (2 π f )]² ------------------(iii)
(a) Now from the question,
m⁺ = mass flow rate = 42,000 kg/s
ρ = density of air = 1.31 kg/m³
vₓ = 250km/h
= 250 x 1000/3600 m/s
= 69.44m/s
∴ vₓ = 69.44m/s
f = number of revolutions per second
= 15rpm
= 15 revolutions per minute
= 15/60 revolutions per second
∴ f = 0.25 revolutions per second
Take π = 3.142 and substitute these values into equation (iii) as follows;
m⁺ = ρ x vₐ x π x [vₓ / (2 π f )]²
42000 = 1.31 x vₐ x 3.142 x [69.44 / (2 x 3.142 x 0.25)]²
42000 = 1.31 x vₐ x 3.142 x [69.44 / 1.571]²
42000 = 1.31 x vₐ x 3.142 x [44.20]²
42000 = 1.31 x vₐ x 3.142 x [1953.64]
42000 = 8041.22 x vₐ
Solve for vₐ;
vₐ = 42000/8041.22
vₐ = 5.223 m/s
Therefore, the average velocity of the air is 5.223m/s
(b) First, let's get the kinetic energy power (Pₓ) of the system as follows;
Pₓ = KE / t
Where;
t = time
Kinetic energy (KE) = (1 / 2) x m x v²
=> Pₓ = (1 / 2) x m x v² / t
=> Pₓ = (1 / 2) x (m / t) x v² -----------------(iv)
Where;
m/t is the mass flow rate = m⁺ = 42000 kg/s
v = velocity of air = vₐ = 5.223 m/s
Substitute these values into equation (iv) as follows;
=> Pₓ = (1 / 2) x (42000) x (5.223)²
=> Pₓ = (1 / 2) x (42000) x (27.280)
=> Pₓ = 572880 W
=> Pₓ = 572.880 kW
Also, the power output (P₀) produced by the turbine is 180kW according to the question.
Now, let's calculate the conversion efficiency (η) of the turbine as follows;
Efficiency = Power Output / Kinetic Energy Power
η = P₀ / Pₓ
Substitute the values of P₀ and Pₓ into the equation to give;
η = 180 kW / 572.880kW
η = 0.314
Therefore the conversion efficiency is 0.314
