The following data is given for a Francis turbine : Net head = 70 m, speed = 600 r.p.m., shaft power = 367.875 kW, overall efficiency = 85% , hydraulic efficiency = 95%, flow ratio = 0.25, breadth ratio = 0.1, outer diameter of the runner = 2 x inner diameter of runner. The thickness of vanes occupy 10% of the circumferential area of the runner. Velocity of flow is constant at inlet and outlet and discharge is radial at outlet. Determine : (i) Guide blade angle, (ii) Runner vane angles at inlet and outlet, (iii) Diameters of runner at inlet and outlet, and (iv) Width of wheel at inlet.

Francis Turbine Design (Advanced)

Problem Statement

Given Data & Constants

Net Head, $H = 70 \, \text{m}$
Speed, $N = 600 \, \text{r.p.m.}$
Shaft Power, $P_s = 367.875 \, \text{kW} = 367875 \, \text{W}$
Overall efficiency, $\eta_o = 85\% = 0.85$
Hydraulic efficiency, $\eta_h = 95\% = 0.95$
Flow ratio, $K_f = 0.25$
Breadth ratio, $n = 0.1$
Diameter ratio, $D_1 = 2 D_2$
Area blockage = 10% (Effective Area Factor = 0.90)
Constant flow velocity: $V_{f1} = V_{f2}$
Radial discharge: $V_{w2} = 0$
Density of water, $\rho = 1000 \, \text{kg/m}^3$
Acceleration due to gravity, $g = 9.81 \, \text{m/s}^2$

Solution

1. Calculate Velocities and Discharge

First, we calculate the velocity of flow based on the head and flow ratio.

$$ V_{f1} = K_f \sqrt{2gH} = 0.25 \sqrt{2 \times 9.81 \times 70} \approx 9.26 \, \text{m/s} $$ $$ \text{Since flow velocity is constant, } V_{f2} = 9.26 \, \text{m/s} $$

Next, find the required discharge (Q) using the overall efficiency and shaft power.

$$ P_w = \frac{P_s}{\eta_o} = \frac{367875}{0.85} = 432794 \, \text{W} $$ $$ Q = \frac{P_w}{\rho g H} = \frac{432794}{1000 \times 9.81 \times 70} \approx 0.63 \, \text{m}^3/\text{s} $$

(iii) & (iv) Diameters and Width of Runner

The discharge is related to the effective flow area at the inlet.

$$ Q = (\text{Effective Area Factor}) \times (\pi D_1 b_1) \times V_{f1} $$ $$ \text{Given } b_1 = n D_1 = 0.1 D_1 $$ $$ 0.63 = 0.90 \times (\pi D_1 \times 0.1 D_1) \times 9.26 $$ $$ 0.63 = 0.90 \times \pi \times 0.1 \times 9.26 \times D_1^2 = 2.618 D_1^2 $$ $$ D_1^2 = \frac{0.63}{2.618} \approx 0.2406 \implies D_1 \approx 0.49 \, \text{m} $$ $$ \text{From the ratios, we find } b_1 \text{ and } D_2: $$ $$ b_1 = 0.1 \times D_1 = 0.1 \times 0.49 = 0.049 \, \text{m} $$ $$ D_2 = D_1 / 2 = 0.49 / 2 = 0.245 \, \text{m} $$

2. Calculate Peripheral Velocities and Whirl Velocity

$$ u_1 = \frac{\pi D_1 N}{60} = \frac{\pi \times 0.49 \times 600}{60} \approx 15.39 \, \text{m/s} $$ $$ u_2 = \frac{\pi D_2 N}{60} = \frac{\pi \times 0.245 \times 600}{60} \approx 7.70 \, \text{m/s} $$

Using the hydraulic efficiency and Euler's equation (with $V_{w2}=0$):

$$ \eta_h = \frac{V_{w1} u_1}{gH} \implies V_{w1} = \frac{\eta_h g H}{u_1} $$ $$ V_{w1} = \frac{0.95 \times 9.81 \times 70}{15.39} \approx 42.34 \, \text{m/s} $$

(i) Guide Blade Angle ($\alpha$)

$$ \tan(\alpha) = \frac{V_{f1}}{V_{w1}} = \frac{9.26}{42.34} \approx 0.2187 $$ $$ \alpha = \arctan(0.2187) \approx 12.33^\circ $$

(ii) Runner Vane Angles at Inlet ($\theta$) and Outlet ($\phi$)

$$ \tan(\theta) = \frac{V_{f1}}{V_{w1} - u_1} = \frac{9.26}{42.34 - 15.39} = \frac{9.26}{26.95} \approx 0.3436 $$ $$ \theta = \arctan(0.3436) \approx 18.96^\circ $$ $$ \tan(\phi) = \frac{V_{f2}}{u_2} = \frac{9.26}{7.70} \approx 1.2026 $$ $$ \phi = \arctan(1.2026) \approx 50.25^\circ $$

Final Design Parameters:

(i) Guide blade angle: $ \alpha \approx 12.33^\circ $

(ii) Runner vane angles: Inlet $ \theta \approx 18.96^\circ $, Outlet $ \phi \approx 50.25^\circ $

(iii) Diameters of runner: Inlet $ D_1 \approx 0.49 \, \text{m} $, Outlet $ D_2 \approx 0.245 \, \text{m} $

(iv) Width of wheel at inlet: $ b_1 \approx 0.049 \, \text{m} $ or $49 \, \text{mm}$

Problem Statement

Given Data & Constants

Solution

1. Calculate Velocities and Discharge

(iii) & (iv) Diameters and Width of Runner

2. Calculate Peripheral Velocities and Whirl Velocity

(i) Guide Blade Angle (\(\alpha\))

(ii) Runner Vane Angles at Inlet (\(\theta\)) and Outlet (\(\phi\))

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Problem Statement

Given Data & Constants

Solution

1. Calculate Velocities and Discharge

(iii) & (iv) Diameters and Width of Runner

2. Calculate Peripheral Velocities and Whirl Velocity

(i) Guide Blade Angle (\(\alpha\))

(ii) Runner Vane Angles at Inlet (\(\theta\)) and Outlet (\(\phi\))

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