STEAM TURBINE 211Area of flow, A = πDh = 3.14 * 0.917 *10
100= 0.288 m^2Now from steam table, for steam dry and saturated at 9.8 bar,
Vs = 0.98 m^3 /kg
Va 1 = 77.65 m/s from velocity trianglesMass flow rate = Va 1 ×A
Vs= 77.65 *0.288
0.198 = 112.95 kg/s(5) Power = m × Vb × (Vt 1 – Vt 0 ) kW
from velocity triangle Vt 1 – Vt 0 = 288 m/spower = 112.95 × 144 ×288
1000= 4682 kW(6) Diagram efficiency = 2 × Vb ×^102
1(V V )
Vtt− = 92.16stage efficiency = diagram efficiency × ηn = 0.9216 × 0.92
Example 2. An impulsive stage of a steam turbine is supplied with dry and saturated steam at
14.7 bar. The stage has a single row of moving blades running at 3600 rev/min. The mean diameter of
the blade disc is 0.9 m. The nozzle angle is 15° and the axial component of the absolute velocity leaving
the nozzle is 93.42 m/s. The height of the nozzles at their exit is 100 mm. The nozzle efficiency is 0.9 and
the blade velocity co-efficiency is 0.966. The exit angle of the moving blades is 2° greater than at the
inlet. Determine:
(1) The blade inlet and outlet angles.
(2) The isentropic heat drop in the stage.
(3) The stage efficiency.
(4) The power developed by the stage.Solution. Mean blade velocity, Vb =DN
60π
= 3.14 × 0.9 ×3600
60 = 169.65 m/s
α = 15° ; Va 1 = 93.42 m/sNow Va 1 = V 1 sin α ; V 1 =^1V
sina
α= 360.95 m/sWith this, inlet velocity triangle can be completed
From there: θ = 29.5° Vr 1 = 202.5 m/s
φ = 29.5 + 2 = 31.5 ; Vr 0 = 0.966 × Vr 1 = 195 m/s
With this, the outlet velocity triangle can be completed
θ = 29.5°, φ = 31.5°
Now for dry and saturated steam at 14.7 bar; Vs = 0.1392 m^3 /kg