Brochure
Q
leakage,1
Q
leakage,2
Q
leakage,1
Q
leakage,3
Q
leakage,1
Q
leakage,4
Q
leakage,1
Q
leakage,2
Q
leakage,1
Q
leakage,3
Q
leakage,1
Q
leakage,4
Q
leakage,1
Q
leakage,2
Q
leakage,1
Q
leakage,3
Q
leakage,1
Q
leakage,4
Q
leakage,1
Q
leakage,2
Q
leakage,1
Q
leakage,3
Q
leakage,1
Q
leakage,4
9393
(5.1)
(5.2)
(5.3)
(5.4)
(5.5)
(5.6)
(5.7)
(5.8)
(5.9)
(5.10)
(5.11)
(5.12)
(5.13)
(5.14)
(5.15)
constantPPP
loss, shaft sealloss, bearingloss, mechanical
=+=
g2
V
HH
2
dyn, inloss, friktion
⋅ ζ = ⋅ ζ =
g2D
LV
fH
h
2
loss, pipe
=
O
A4
D
h
=
ν
=
h
VD
Re
Re
64
f
laminar
=
0.0047
32mm
0.15mm
k/D Relative roughness:
110500
sm101
0.032m3.45m s
VD
Re
Reynolds number:
sm3.45
m0.032
4
sm(10/3600)
A
Q
VMean velocity:
h
26
h
22
3
==
=
⋅
⋅
=
ν
=
=
π
==
−
sm
sm
gD
LV
f
H
h
loss, pipe
1.2 m
9.8120.032m
)3.45(2m
0.031
2
Pipe loss:
2
2
2
=
⋅⋅
⋅
==
g2
V
HH
2
1
dyn,1loss, expansion
⋅ ζ
=
⋅ ζ =
2
2
1
A
A
1
− = ζ
g2
V
A
A
1H
2
0
2
2
0
loss, contraction
⋅
− =
g2
V
HH
2
2
dyn,2
loss, contraction
⋅ζ=⋅ζ=
g2
ww
g2
w
H
2
1, kanal1
2
s
loss, incidence
⋅
−
ϕ=
⋅
ϕ=
2
2
design1
loss, incidence
k)QQ(kH +−⋅=
m
22
6
4
22
3
2
loss, disk
DU
102
103.7k
)e5D(DUkρ
P
⋅ ν
⋅ =
+ =
−
( ) ( )
( )
( )
B
5
2
3
A
5
2
3
B
loss, disk
A
loss, disk
Dn
Dn
PP =
(5.16)
(5.17)
(5.18)
(5.19)
leakageimpeller
QQQ +=
( )
g8
DD
HH
2
gap
2
2
2
stat, impellerstat, gap
−
ω − =
g2
V
1.0
g2
V
s
L
f
g2
V
0.5H
222
stat, gap
++=
gap
leakage
stat, gap
VA
Q
1.5
s
L
f
2gH
V
=
+
=
where
Q
impeller
= Flow through impeller [m
3
/s], Q
= Flow through pump [m
3
/s] , Q
leakage
= Leakage flow [m
3
/s]
Leakage occurs many dierent places in the pump and depends on the pump
type. Figure 5.15 shows where leakage typically occurs. The pressure dier-
ences in the pump which drives the leakage flow as shown in figure 5.16.
The leakage between the impeller and the casing at impeller eye and
through axial relief are typically of the same size. The leakage flow between
guidevane and shaft in multi-stage pumps are less important because both
pressure dierence and gap area are smaller.
To minimise the leakage flow, it is important to make the gaps as small as
possible. When the pressure dierence across the gap is large, it is in par-
ticular important that the gaps are small.
Model
The leakage can be calculated by combining two dierent expressions for
the dierence in head across the gap: The head dierence generated by
the impeller, equation (5.17) and the head loss for the flow through the gap
equation (5.18). Both expressions are necessary to calculate the leak flow.
In the following an example of the leakage between impeller eye and pump
housing is shown. First the dierence in head across the gap generated by
the impeller is calculated. The head dierence across the gap depends on
the static head above the impeller and of the flow behaviour in the cavity
between impeller and pump casing:
(5.1)
(5.2)
(5.3)
(5.4)
(5.5)
(5.6)
(5.7)
(5.8)
(5.9)
(5.10)
(5.11)
(5.12)
(5.13)
(5.14)
(5.15)
constantPPP
loss, shaft sealloss, bearingloss, mechanical
=+=
g2
V
HH
2
dyn, inloss, friktion
⋅ ζ = ⋅ ζ =
g2D
LV
fH
h
2
loss, pipe
=
O
A4
D
h
=
ν
=
h
VD
Re
Re
64
f
laminar
=
0.0047
32mm
0.15mm
k/D Relative roughness:
110500
sm101
0.032m3.45m s
VD
Re
Reynolds number:
sm3.45
m0.032
4
sm(10/3600)
A
Q
VMean velocity:
h
26
h
22
3
==
=
⋅
⋅
=
ν
=
=
π
==
−
sm
sm
gD
LV
f
H
h
loss, pipe
1.2 m
9.8120.032m
)3.45(2m
0.031
2
Pipe loss:
2
2
2
=
⋅⋅
⋅
==
g2
V
HH
2
1
dyn,1loss, expansion
⋅ ζ
=
⋅ ζ =
2
2
1
A
A
1
− = ζ
g2
V
A
A
1H
2
0
2
2
0
loss, contraction
⋅
− =
g2
V
HH
2
2
dyn,2
loss, contraction
⋅ζ=⋅ζ=
g2
ww
g2
w
H
2
1, kanal1
2
s
loss, incidence
⋅
−
ϕ=
⋅
ϕ=
2
2
design1
loss, incidence
k)QQ(kH +−⋅=
m
22
6
4
22
3
2
loss, disk
DU
102
103.7k
)e5D(DUkρ
P
⋅ ν
⋅ =
+ =
−
( ) ( )
( )
( )
B
5
2
3
A
5
2
3
B
loss, disk
A
loss, disk
Dn
Dn
PP =
(5.16)
(5.17)
(5.18)
(5.19)
leakageimpeller
QQQ +=
( )
g8
DD
HH
2
gap
2
2
2
stat, impellerstat, gap
−
ω − =
g2
V
1.0
g2
V
s
L
f
g2
V
0.5H
222
stat, gap
++=
gap
leakage
stat, gap
VA
Q
1.5
s
L
f
2gH
V
=
+
=
Leakage between impeller eye and
pump casing.
Leakage above blades in an open
impeller
Leakage between guidevanes and shaft in a
multi-stage pump
Leakage as a result of balancing holes
Figure 5.15: Types of leakage