CIV E 444 - APPLIED HYDRAULICS
SPRING 2016
HOMEWORK No. 12 SOLUTION

D = 30 cm = 0.30 m
n = 1200 rpm / (60 s/m) = 20 rps
C_Q = Q / (n D³) = 0.25 / [ 20 × (0.3)³ ] = 0.463
From the given figure, with C_Q = 0.463, find C_H = 1.24, and C_P = 0.72
ΔH = C_H D² n² / g = 1.24 (0.3)² (20)² / 9.81 = 4.55 m
ρ = 1 KN ⋅ s²/m⁴
P = C_P ρ D⁵ n³ = 0.72 (1) (0.3)⁵ (20)³ [KN ⋅ m/s]
P = 14 KN ⋅ m/s = 14 KW

From the first figure, at maximum efficiency: ΔH = 95 m, and Q = 0.214 m³/s
( C_H ) _N = ( C_H ) _{N = 2133.5}
[ ΔH / (D²n² / g) ] _N = [ ΔH / (D²n² / g) ] _{N = 2133.5}
[ ΔH / (n²) ] _N = [ ΔH / (n²) ] _{N = 2133.5}
80 / N² = 95 / (2133.5)²
N = 2133.5 (80/95)^1/2 = 1958 RPM
(C_Q)_{N = 1958} = (C_Q) _{N = 2133.5}
[Q / (nD³)] _{N = 1958} = [Q / (nD³)] _{N = 2133.5}
Q_{N = 1958} / Q_{N = 2133.5} = 1958 / 2133.5 = 0.917
Q_{N = 1958} = 0.917 Q_{N = 2133.5} = 0.917 × 0.214 = 0.196 m³/s
n = 1958 / 60 = 32.63 rps
D = 0.371 m
C_Q = Q / (nD³) = 0.196 / [ 32.63 × (0.371)³ ] = 0.118

From the second figure: C_P = 0.68
C_P = P / (ρ D⁵ n³)
ρ = 1 KN ⋅ s²/m⁴
P = 0.68 ρ D⁵ n³ = 0.68 × 1 × (0.371)⁵ (32.63)³ [KN ⋅ m/ s]
P = 166 KN ⋅ m/ s = 166 KW

h_p = (z₂ - z₁) + [V²/(2g)] [f (L/D) + ∑ K_L ]
h_p = (z₂ - z₁) + [ Q²/(2gA²)] [ f (L/D) + K_e + K_b + K_E ]
From Table 5-3 (in the text): K_e = 0.5; K_b = 0.35; K_E = 1
h_p = (230 - 200) + [ Q²/(2g ((π/4) D²)²) ] [ 0.015 (1000/0.4) + 0.5 + 0.35 + 1 ]
h_p = 30 + [ Q²/(2 (9.81) (π/4)² (0.4)⁴) ] (39.35)
h_p = 30 + [ Q²/(0.3098) ] (39.35)
h_p = 30 + 127.02 Q²
Pump performance curve: H = 55 - 500 Q ²
At H = h_p: Q = 0.2 m³/s
h_p = 30 + 127.02 (0.2)² = 35.08 m.