APPLIED INDUSTRIAL ENERGY AND ENVIRONMENTAL MANAGEMENT
Z. K. Morvay, D. D. Gvozdenac
Part III:
FUNDAMENTALS FOR ANALYSIS AND CALCULATION OF ENERGY AND
ENVIRONMENTAL PERFORMANCE
1
Applied Industrial Energy and Environmental Management Zoran K. Morvay and Dusan D. Gvozdenac © John Wiley & Sons, Ltd
Toolbox 8
PUMPS and FANS
PUMPS 1. There are two types of modern pump applied in industry: (a) Velocity head and (b) Positive
displacement. The following categorization of pumps could be applied:
(a) Velocity head
Centrifugal:
– Axial flow (single or multistage)
– Radial flow (single or double suction)
– Mixed flow (single or double suction)
- Peripheral (single or multistage)
Special effect:
– Gas lift
– Jet
– Hydraulic ram
– Electromagnetic
(b) Positive displacement:
Reciprocating:
– Piston plunger
– Diaphragm (mechanically or fluid driven, simplex or
multiplex)
Rotary:
– Single rotor (vane, piston, screw, flexible member,
peristaltic)
– Multiple rotor (gear, lobe, screw, circumferential
piston)
Centrifugal pumps are used in more industrial applications than any other kind of pump. The main
reason is than these pumps offer low investment and maintenance costs. These pumps have been
limited to low-pressure-head applications, but modern pumps are designed for quite high pressures.
These pumps have a smooth flow and the ability to tolerate non-flow conditions.
The main parts of the centrifugal pump are the impeller and volute (Fig. 8.1). An impeller can
take many forms. This device imparts a radial velocity to the fluid that has entered the pump
perpendicular to the impeller. The volute performs the function of slowing the fluid and increasing the
pressure. There may be one or more more volutes. The number of stages in the pump greatly affects
the pump’s output characteristics. Several stages can be incorporated into the same casing, with an
associated increase in pump output. Multistage pumps are often used for applications with a total
developed head of over 50 bar.
Whether or not a pump is self-priming can be important. If a centrifugal pump is filled with air
when it is turned on, the initiation of pumping action may not be sufficient to bring the fluid into the
pump. Pumps can be specified with features that can minimize priming problems.
Part III – Toolbox 8:
PUMPS and FANS 2
Impeller
Volute
Rotation
Figure 8.1: Schema of a Centrifugal Pump
PistonSuction
valve
Discharge
valve
H
Figure 8.2: Scheme of Positive-Displacement Pump
(Piston Type)
Positive-displacement pumps demonstrate high
discharge pressure and low flow rates and, usually, this
is accomplished with some flow pulsation. A piston
pump (Fig. 8.2) is a classic example of this type of
pump. Reciprocating pumps offer very high
efficiencies. For the larger sizes of these pumps it
reaches 90 %. These types of pump are more
appropriate for pumping abrasive liquids than are
centrifugal pumps.
Rotary pumps (Fig. 8.3) are one type of positive-
displacement pump that does not impart pulsations to
the exit flow.
Figure 8.3: Scheme of Rotary pump
Positive-displacement pumps require special seals to contain the fluid. The costs are higher for
both investment and for maintenance compared with most pumps that operate on a velocity head
basis. Positive-displacement pumps demonstrate an efficiency that is nearly independent of the flow
rate, in contrast to the velocity head types.
For positive-displacement it is important to stress that the output flow is proportional to pump
speed. This allows this type of pump to be used for metering applications. Also, a positive aspect of
these pumps is that they are self-priming, except at initial start-up.
If the downstream flow is blocked, high head pressure can be developed in a positive-
displacement pump and the pump could be damaged. For this reason, a pressure relief valve bypass
must be used when a positive-displacement pump is used.
2. Pumps are applied mainly for the following purposes:
circulation of fluids;
supplying the processes;
transferring the fluids.
Typical percentages for industrial pump application are presented in Fig. 8.4.
Part III – Toolbox 8:
PUMPS and FANS 3
Circulation
58%
Supply
36%
Transfer
6%
Figure 8.4: Pump Application in Industrial Practice
3. The number of pumps versus a pump's power in industrial practice is presented in Fig. 8.5. Peak
pump powers range from 3.5 to 15.0 kW.
0.0
2.0
4.0
6.0
8.0
10.0
12.0
14.0
0.2
5
0.4
0
0.7
5
1.5
0
2.2
0
3.7
0
5.5
0
7.5
0
11
.00
15
.00
18
.50
22
.00
30
.00
37
.00
45
.00
55
.00
75
.00
90
.00
Output power of the motor [kW]
Perc
enta
ge [%
]
Analysis was performed on the sample of 3500 pumps
Figure 8.5: Pump Power Occurrences in Industry
4. The cost of electricity for running the pump is shown in Table 8.1. The calculation is performed for
4600 and 8500 operating hours of the pump per year and for the most frequently used power of the
pump. The life cycle of a pump can be estimated as 10 or 15 years. In this case the investment and
maintenance cost of the pump can be estimated as 5 % of the total cost for running the pump in that
period with operating hours of between 4600 and 8500 per year. That means that if some reasonable
investment is made for improving the energy efficiency of the pump, the pay back period will be very
short.
Part III – Toolbox 8:
PUMPS and FANS 4
Table 8.1: Cost of Electrical Energy of Pump [US$] (1kWh = 0.045 US$) Power of
pump
kW
Annual operating hours of pump
4600 h/year
Annual operating hours of pump
8500 h/year
1 year 5 years 10 years 15 years 1 year 5 years 10 years 15 years
2.2 455 2277 4554 6831 842 4208 8415 12623
3.7 766 3830 7659 11 489 1415 7076 14 153 21 229
5.5 1139 5693 11 385 17 078 2104 10 519 21 038 31 556
7.5 1553 7763 15 525 23 288 2869 14 344 28 688 43 031
11.0 2277 11 385 22 770 34 155 4208 21 038 42 075 63 113
15.0 3105 15 525 31 050 46 575 5738 28 688 57 375 86 063
18.5 3830 19 148 38 295 57 443 7076 35 381 70 763 106 144
22.0 4554 22 770 45 540 68 310 8415 42 075 84 150 126 225
5. The relation that determines the total head developed by the pump is as follows:
hHg
ppH g
12 (8.1)
where:
H = Total head developed by pump in meters of the column of the liquid being pumped,
[m]
p2, p1 = Pressure in delivery and suction space, respectively, [Pa]
= Density of the liquid being pumped, [kg/m3]
Hg = Geometrical height to which liquid is lifted, [m] h = Head of the pump required for creating a velocity and for overcoming friction
resistance in the pipes and local obstacles in both suction and delivery lines, [m]
g = Acceleration due to gravity, = 9.81 [m/s2] commonly
Eq. (1) is used when designing pump installation.
The notations used in Eq. (1) are presented in Fig. 8.6.
H
H g
p d
p s
p 1
p 2
Figure 8.6: Pump Installation
Part III – Toolbox 8:
PUMPS and FANS 5
6. Total head (H) can be also calculated by using the network equation:
2
wwH
g
ppH
2s
2d
0sd (8.2)
where:
pd = Delivery pressure at the outlet of the pump, [Pa]
ps = Suction pressure of the pump, [Pa]
H0 = Vertical distance between the measuring points of pressure pd and ps, [m]
wd = Velocity of fluid in the delivery (supply) pipeline, [m/s]
ws = Velocity of fluid in the suction pipeline, [m/s]
This equation is used for network characteristic determination.
7. The possible piping arrangements. Some possible piping arrangements are presented in Fig. 8.7.
Total static head is defined as the vertical distance from the surface of the source of the liquid supply
to the free surface of the liquid in the discharge receiver or to the point of free discharge from the
discharge pipe. When both the suction and discharge surfaces are open to the atmosphere, the total
static head equals the vertical difference in elevation. For calculations one must use the free-surface
elevations that cause the maximum suction lift and discharge head. That means that the lowest
possible level in the supply tank and the highest possible level in the discharge tank or pipe have to be
used. If the supply source is below the pump shaft line, the vertical distance is called static suction
head. With supply above the pump shaft line, the vertical distance is called static suction head. If the
liquid level varies during the pump operation, the lowest liquid level has to be used for calculating the
total static head.
Part III – Toolbox 8:
PUMPS and FANS 6
(a) Suction lift and
submerged discharge
Pump shaft
Static discharge
head
Static suction
head
To
tal sta
tic h
ead
(b) Suction lift and free
discharge
Pump shaft
Static suction
head
To
tal sta
tic h
ead
Static discharge
head
(c) Suction lift and varying
discharge head
Pump shaft
Static discharge
head
Static suction
head
To
tal sta
tic h
ead
(d) Static suction head and
submerged discharge
Pump shaftStatic suction
head
Total static head
Static discharge
head
Free discharge
Maximum level
(e) Static suction head and
discharge head due to elevation
and pressure in the tank
Pump shaft
Static discharge head
(Tank pressure has to
be added)
Static suction
head
To
tal sta
tic h
ead
(f) Static suction head and
varying discharge
Pump shaftStatic suction
head
Total static head
Static discharge
head
Pressurized tank
Maximum level
Figure 8.7: Typical Pump Suction and Discharge Piping Arrangements
8. There are numbers of combinations of how the elements of network and pumps can be connected.
A number of characteristic connections are as follows:
friction losses without static head (Fig. 8.8);
friction losses with static head (Fig. 8.9);
system with two discharge heads (Fig. 8.10);
negative lift (gravity head) (Fig. 8.11).
He
ad
Flow rate
Friction
losses
System
friction curve
Figure 8.8: Friction Losses without Static Head
Part III – Toolbox 8:
PUMPS and FANS 7
He
ad
Flow rate
Friction
losses
System
friction curveHs
Hs
Figure 8.9: Friction Losses with Static Head
He
ad
Flow rate
Friction
losses
System
friction curveHs
Hs
Figure 8.10: System with Two Different Discharged Heads
He
ad
Flow rate
Hs
Hs
Figure 8.11: Negative Lift (Gravity Head)
9. Plotting Eqs (8.1) and (8.2), the intersection of the two curves gives the Working Point of the
system formed by the network and pump which serve the given network.
Generally, the characteristics of the network can be expressed by the following equation:
2
g VaH p (8.3)
Part III – Toolbox 8:
PUMPS and FANS 8
where:
p = Pressure drop in meters of liquid is being pumped, [m]
a = Characteristics of the network, [m s2/m
6]
Hg = Geometrical height to which liquid is lifted, [m]
An example of pump and network characteristics for Hg = 0 is presented in Fig. 8.12.
0
5
10
15
20
25
30
35
40
0 1 2 3 4 5 6 7 8 9
Volume flow rate [m3/s]
He
ad
an
d p
ressu
re lo
sse
s o
f n
etw
ork
[m
]
Head of pump
Network characteristic
Figure 8.12: Head and Network’s Pressure Losses versus Flow Rate
10. Mass and volume flow rates relation:
V m (8.4)
where:
m = Mass flow rate of fluid, [kg/s]
= Density, [kg/m3]
V = Volume flow rate of fluid, [m3/s]
11. The power of the electrical motor of the pump is:
1000
HgVN (8.5)
where:
V = Volume output (delivery) of the pump, [m3/s]
H = Total head developed by pump in meters of the column of the liquid being pumped, [m]
= Overall efficiency of the pump installation equal to the product of the efficiencies of the
pump p, the transmission tr, and the electrical motor m (= p· tr· m)
The motor installed for a pump has a somewhat greater power Ninst than that needed by the pump in
order to provide a reserve for possible overloading:
N Ninst (8.6)
Part III – Toolbox 8:
PUMPS and FANS 9
The power reserve factor is taken depending on the value of N and is given in Table 8.2.
Table 8.2: Power reserve factor N [kW]
< 1 2.0–1.5
1–5 1.5–1.2
5 –50 1.2–1.15
> 50 1.1
12. Power of three-phase electrical motors. Asynchronous three-phase electrical motors are the
most common motors used in industry. The power taken from grid for these motors (and synchronous
also) is as follows:
]W[cosIU3N ll (8.7)
where:
Ul = line voltage, [V]
Il = line current, [A]
cos = power factor, [-]
or,
]W[cosIU3N pp (8.8)
where:
Up = phase voltage, [V]
Ip = phase current, [A]
An example of a three-phase symmetric circuit is presented in Fig. 8.13.
220 V
220 V
220 V
Phase 1
Phase 2
Phase 3
Up = 220 V
Ul = 380 VZero
Figure 8.13: Three-Phase Symmetric Circuit
13. By changing the speed of a centrifugal pump within a limited range, the changes in its flow rate,
head and power consumed are defined by the following relations:
2
1
2
1
n
n
V
V (8.9)
2
2
1
2
1
n
n
H
H (8.10)
Part III – Toolbox 8:
PUMPS and FANS 10
3
2
1
2
1
n
n
N
N (8.11)
Where:
V = Volume output (delivery) of the pump, [m3/s]
H = Total head developed by the pump in meters of the column of the liquid being pumped,
[m]
N = Power of electrical motor of pump, [kW]
n = Speed of pump, [rpm]
14. The suction height of a centrifugal pump is calculated by using the following relation:
cavs,1satas hhhPH (8.12)
where:
Pa = Atmospheric pressure
hsat = Saturated vapor pressure of the liquid being sucked in at the pumping temperature
h1,s = Hydraulic resistance of the suction line including the energy needed for imparting a
velocity to the flow of liquid
hcav = Cavitation correction (a reduction in the suction height to avoid cavitation) depending on
the volume flow rate of the pump [m3/s] and the speed [rpm].
The cavitation correction can be determined by using the following equation:
67.02
cav nV00125.0h (8.13)
All values in Eq. (8.12) are expressed in meters of the column of the liquid being pumped.
15. Cavitation is a local condition that allows liquid to boil and form a vapor. The pump application
shown in Fig. 14 is a once-through system. However, the leg of piping though pressure drop 1 shown
there can have some important implications related to net positive suction head. Net positive suction
head (NPSH) is the difference between the local absolute pressure of a liquid and the thermodynamic
saturation pressure of the liquid based upon the temperature of the liquid. If NPSH = 0, the liquid can
vaporize, and this can result in a variety of outcomes from noisy pump operation to outright failure of
components. Cavitation, if it occurs, will take place at the lowest pressure point and this point is
located at the inlet of the pump or inside the pump. Most manufacturers specify how much NSPH is
required for the satisfactory operation of their pumps. Actual net positive suction head (NPSHA) is
the NPSH at the given state of operation of a pump and must be larger than the required net positive
suction head (NPSHR) specified by the manufacturer for a given application.
Part III – Toolbox 8:
PUMPS and FANS 11
PUMPPressure
drop 2
Pressure
drop 1
FLOW
TANK
Figure 8.14: Typical Pump Application
16. The output of piston pump V [m3/s] is:
Single acting and differential (trim) pumps:
60
nsAV V (8.14)
Double-acting pumps:
60
nsAA2V r
v (8.15)
where:
V = Delivery factor (from 0.8 to 0.9), [-]
A = Cross-sectional area of the piston, [m2]
Ar = Cross-sectional area of the road, [m2]
s = Piston stroke, [m]
n = Speed of rotation (number of double piston strokes per minute), [rpm]
17. The output of a gear pump V [m3/s] is:
60
nzbA2V 1
v (8.16)
where:
V = Delivery factor, [-]
A1 = Cross-sectional area of a tooth restricted by addendum circle of the matrix gear wheel,
[m2]
b = Width of a tooth, [m]
z = Number of teeth on a gear wheel, [-]
n = Speed of rotation (number of double piston strokes per minute), [rpm]
18. There are many possibilities for reducing the energy consumption of pumps. All of these energy
conservation measures can be specified in two groups (Fig. 8.15):
Part III – Toolbox 8:
PUMPS and FANS 12
a) Effective operation
b) Increasing the efficiency of the motor and/or pump
However, the effect of the possible technical measures which can be applied is different and
always has to be analyzed simultaneously with: (a) operational conditions of pump, (b) economical
aspects and (c) possible influence of its application on process. Adjusting pump performance to meet
process requirements is the most effective way of reducing energy cost (Fig. 8.16) and improving the
efficiency of both motor and pump (Fig. 8.17) can result only in energy cost reduction by a small
percentage.
Reduce Impeller Diameter
Adjust Speed
Change Model
Select Running Pump(s)
Reduce Pipe Loss
Effective
Operation
Raise Up
Efficiency
Pump
Efficiency
Motor
Efficiency
Improve
System
Adjust Pump
Performance
Figure 8.15: Ways to Reduce the Energy Consumption of a Pump
He
ad
[m
WC
] a
nd
Sh
aft P
ow
er
[kW
]
Volume flow rate [m3/s
Losses
HEAD
POWER
Figure 8.16: Adjustment of Pump Performance
He
ad
[m
WC
],
Effic
ien
cy [%
] a
nd
Sh
aft P
ow
er
[kW
]
Volume flow rate [m3/s]
HEAD
POWER
EFFICIENCY
Figure 8.17: Increasing Efficiency of Pump
and/or Motor
Part III – Toolbox 8:
PUMPS and FANS 13
19. Check list of centrifugal pump faults and their causes:
SYMPTOM POSSIBLE CAUSE OF TROUBLE
FAILS TO DELIVER LIQUID
1. Wrong direction of rotation
2. Pump not primed
3. Suction line not filled with liquid 4. Air or vapor pocket in suction line
5. Inlet to suction pipe not sufficiently submerged
6. Available net positive suction head (NPSH) not high enough 7. Height from suction liquid level to pump shaft too great
8. Distance from suction liquid level to pump shaft too small
9. Difference between suction pressure and vapor pressure too small 10. Pump not up to rated speed
11. Total head greater that head for which pump is designed
PUMP DOES NOT DELIVER
RATED CAPACITY
1. Wrong direction of rotation
2. Suction line not filled with liquid 3. Air or vapor pocket in suction line
4. Air leaks in suction line or through stuffing boxes
5. Suction pipe intake not submerged enough 6. Available NPSH not sufficient
7. Height from liquid level to pump shaft too great 8. Distance from suction liquid level to pump shaft too small
9. Difference between suction pressure and vapor pressure too small
10. Pump not up to rated speed 11. Total head greater than head for which pump was designed
12. Foot valve too small
13. Foot valve clogged with trash 14. Viscosity of liquid greater than that for which pump was designed
15. Mechanical defects (wearing rings worn, impeller damaged, internal leaks caused by
defective gaskets)
PUMP’S DISCHARGE
PRESSURE LOW
1. Gas or vapor in liquid 2. Pump not up to rated speed
3. Greater discharge pressure needed than that for which pump was designed
4. Liquid thicker than that for which pump was designed 5. Wrong rotation
6. Mechanical defects (wearing rings worn, impeller damaged, internal leaks caused by
defective gaskets)
STUFFING BOXES
OVERHEAT
1. Packing too tight
2. Packing not lubricating
3. Wrong grade of packing 4. Not enough cooling water to jacket
5. Stuffing box improperly packed
PUMP LOSSES PRIME
AFTER STARTING
1. Suction line not filled with liquid
2. Air leaks in suction line or through stuffing boxes 3. Gas or vapor in liquid
4. Air or vapor pocket in suction line 5. Inlet to suction line not submerged far enough
6. Available NPSH not sufficient
7. Height from liquid level to pump shaft too great 8. Distance from suction liquid level to pump shaft too small
9. Difference between suction and vapor pressure too small
10. Liquid seal piping to lantern ring plugged 11. Lantern ring not properly placed in stuffing box
PUMP OVERLOADS
DRIVER
1. Speed too high
2. Total head lower than rated head
3. Either the specific gravity or viscosity of liquid or both different from that for which pump is rated
4. Mechanical defects (misalignment, shaft bent, rotating elements dragging, packing too tight)
VIBRATION
1. Starved suction (gas or vapor in liquid, available not positive suction head not high enough, inlet to suction line not submerged enough, gas or vapor pockets in suction line)
2. Misalignment
3. Warn or loose bearings 4. Rotor out of balance (impeller being plugged or damaged)
5. Shaft bent
6. Control valve in discharge line improperly placed 7. Foundation not rigid
BEARINGS OVERHEAT
1. Oil level too low
2. Improper or poor grade of oil
3. Dirt in bearings 4. Dirt in oil
5. Moisture in oil 6. Oil cooler clogged or scaled
Part III – Toolbox 8:
PUMPS and FANS 14
7. Any failure of oiling system
8. Not enough cooling water
9. Bearing too tight 10. Oil seats fitted too closely on shaft
11. Misalignment
BEARINGS WEAR RAPIDLY
1. Misalignment 2. Shaft bent
3. Vibration
4. Excessive thrust resulting from mechanical failure inside the pump 5. Lack of lubricant
6. Bearings improperly installed
7. Dirt in bearings 8. Moisture in oil
9. Excessive cooling of bearings
FANS
20. Generally, fans are classified according to how the gas flows through the impeller. These flows
may be axial, radial, mixed and cross.
The typical characteristics of fans are shown in Fig. 8.18. Fan efficiency variations indicate a
sharp maximum value at the design point. That means that choosing the fan must be tuned carefully to
the required conditions.
Volume flow rate
Total p
Efficiency
Power
Figure 8.18: Typical Characteristics of a Centrifugal Fan
Two typical fans, most frequently used in industry, are presented in Figs 8.19 and 8.20. There are
a number of vane types and these types can also be used for fan classification. Axial fans (Fig. 8.20)
usually have vanes of an airfoil shape or vanes of uniform thickness. Some types of vane that can be
found on centrifugal fans are presented in Fig. 8.19.
Most industrial applications use centrifugal type of fans. Compared with axial fans they have a
higher pressure rise, but a lower flow rate.
Part III – Toolbox 8:
PUMPS and FANS 15
Rotation
Impeller
Van
Backward inclined
Some possible vane types:
Forward curved
Radial
Airfoil
Backward curved
Tubular
Volute
Figure 8.19: Some Vane Types that Might be Used on a Centrifugal
Fan
Impeller
Figure 8.20: Axial Fan
21. The pressure increase created by a fan (Fig. 8.21) or total head of fan (H) is:
zg)(2
w)pp(ppp air
2
ds12 (8.17)
or
2
wp
2
wpp
2s
s,st
2d
d,st (8.18)
where:
p1 = Pressure in the volume from which the fan takes the gas, [Pa]
p2 = Pressure in the volume into which the fan delivers the gas, [Pa]
ps, pd = Pressure drops in suction and delivery lines, [Pa]
w = Velocity of gas at the outlet from the installation, [m/s]
pst,d, pst,s = Static pressures directly after the fan and before it, [Pa]
wd, ws = Velocities of gas in delivery and suction pipelines, [m/s]
= Density of gas, [kg/m3]
air = Density of ambient air, [kg/m3]
z = Difference between heights of the delivery and suction places, [m]
22. The power of the fan is:
]kW[1000
PVN (8.19)
where:
V = Volume flow rate, [m3/s]
P = Total head of fan, [Pa]
= Overall efficiency of the fan installation equal to the product of pump efficiency p, the
transmission tr, and the electrical motor m (= p tr m)
Part III – Toolbox 8:
PUMPS and FANS 16
P2
P1
sP
pP
w
z
Figure 8.21: Fan Installation
23. Fan flow control is a very important design and operation concern. There are five types of controls
used for forced- and induced- draft fans:
damper in the duct with constant-speed fan drive;
two-speed fan driver;
variable inlet vanes or inlet louvers with a constant-speed drive;
multiple-step variable fan drive;
variable speed drive.
Dampers are the least expensive to install, but also the most inefficient in terms of energy use. A
variable speed drive control system is the preferred control system, when a combination of initial and
operating costs is considered.
24. EXAMPLES
Example 1: A solution (3m/kg1120 ) has to be fed at a flow rate of 115 m
3/h from a tank
into an apparatus at a height of 10.8 m above the liquid level in the tank. The gauge pressure in the
apparatus is 0.4 barg and the pressure in the tank is atmospheric. The pipeline has diameter of
mm5.4140 . Its total equivalent length (the actual length plus the equivalent length of the local
obstacles) is 140 m. The coefficient of friction resistance in the pipeline is 03.0 .
The centrifugal pump envisaged for this job was tested at a speed of 1200 rpm and the following
results were obtained:
V [l/s] 0 10.8 21.2 29.8 40.4 51.1
H [m] 23.5 25.8 25.4 22.1 17.3 11.9
P [kW] 5.16 7.87 10.1 11.3 12.0 18.5
The liquid density during the testing of the pump was 3m/kg1120 .
It needs to be checked as to whether is it possible to use this pump for the proposed pumping
under the prescribed conditions.
Part III – Toolbox 8:
PUMPS and FANS 17
Solution:
Pump
The efficiency of the pump is (see Eq. (8.3)):
P1000
HgV (8.20)
V [l/s] 0 10.8 21.2 29.8 40.4 51.1
[-] 0.000 0.389 0.586 0.640 0.640 0.361
The pump’s characteristics are presented in Fig. 8.22 and the poly trend line are as follows:
11223446 102.3480 + V103.6455 + V101.1604 -V101.5357 - V103.0219H (8.21
)
5.1756 +V109.1191 + V102.3995 + V101.0747 - V101.3111N 2223345 (8.22
) -42233547 108.1892 - V105.2564 + V101.8843 - V104.1539 + V10-4.3201 (8.23
)
0
5
10
15
20
25
30
35
0 10 20 30 40 50 60
Volume flow rate [l/s]
Head [m
] and P
ow
er
[kW
]
0.000
0.100
0.200
0.300
0.400
0.500
0.600
0.700
Effic
iency [-]
n=1200 rpm
Density = 1120 kg/m3
Efficiency [-]
Power [kW]
Head [m]
Figure 8.22: Pump Characteristics
Pump and system characteristics
The fluid velocity is:
];s/m[37.2
4
131.0
3600
115
w2
]m[2863.081.92
37.2h
2
w (8.24
)
The loss of head for overcoming the pipe resistance and local obstacles is:
Part III – Toolbox 8:
PUMPS and FANS 18
]m[1791.92863.0131.0
14003.0h
D
)LL(h w
eq
lf (8.25
)
The required total head of the pump is (Eq. (8.1)):
]m[9060.232863.01791.98.10112081.9
000,1004.0H
(8.26
)
This total head is calculated for a volume flow rate of 31.94 [l/s].
The tested pump has to be used for a described duty, but, plotting the working point (V = 31.94
l/s; H = 23.906 m) in Fig. 8.22 one can see that this point is above the curve of the pump
characteristics and, consequently, the pump at n = 1200 rpm cannot ensure the required output. At H =
23.906 m the pump delivered only 25.67 l/s (poly trend curve H = f(V) can be used too). However, by
increasing the pump’s speed, it will be possible to reach the desired working point. Using Eqs (8.6)
and (8.7) the experimental data can be recalculated for a new speed of pump. If the speed is nnew =
1260 rpm, the recalculated pump characteristics are as follows:
V [l/s] 0.00 11.34 22.26 31.29 42.42 53.66
H [m] 25.91 28.44 28.00 24.37 19.07 13.12
P [kW] 5.97 9.11 11.69 13.08 13.89 21.42
[-] 0.000 0.389 0.586 0.640 0.640 0.361
The working point and new head-volume flow rate curve for a speed of pump of 1260 rpm are
presented in Fig. 8.23.
0.00
5.00
10.00
15.00
20.00
25.00
30.00
35.00
0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 40.00 45.00
Volume flow rate [l/s]
Head [m
]
Working pointn = 1200 rpm
n = 1260 rpm
Figure 8.23: Pump Characteristics for 1200 and 1260 rpm and Working Point
By increasing the speed of pump from 1200 to 1260 rpm, the pump can ensure the required flow
rate of 31.94 l/s (115 m3/h) and head of 23.91 m. The power of the pump is, taking the power from the
Fig. 8.22 or calculating the power from the poly trend line for real volume flow rate (31.94 l/s):
]kW[96.121200
1260194.11
n
nPP
33
newnew
(8.27
)
Part III – Toolbox 8:
PUMPS and FANS 19
Example 2: A centrifugal fan was tested at a speed of n = 1440 rpm. The following results
were obtained:
V m3/h 100 350 700 1000 1600 2000
p Pa 449 424 432 427 387 316
The resistance of the network calculations shows that when air flows through it at a rate of 1350 m3/h,
the pressure losses are Pa85pw and Pa288pp lf . The difference between the pressures in
the delivery and the suction spaces for the calculated network is Pa128pp .
If the testing fan is installed in a described network, the volume flow rate of air has to be
calculated.
Solution:
Network
A parabola expresses the characteristics of the network:
2Vbap (8.28
)
The first addend in the right-hand side does not depend on the flow rate and is the difference between
the pressures in the delivery and suction spaces. The second is equal to the sum of pressure losses
lfw ppp and changes proportionally to the square of the flow rate. That means that
characteristics of the network are:
22
t 1350
V373128
V
V)28885(128p
(8.29
)
where p is in Pa and (V/1350) is the ratio of the actual flow rate and the calculated value of flow
rate based on the resistance of the network.
0
100
200
300
400
500
600
700
800
900
1000
0 200 400 600 800 1000 1200 1400 1600 1800 2000
Volume flow rate [m3/h]
Pre
ssure
dro
p [P
a]
Network
Working
pointFan
Figure 8.24: Fan and Network Head versus Flow Rate
Part III – Toolbox 8:
PUMPS and FANS 20
The working point is the intersection of two characteristics (fan and network) and it shows that in
operation for the given network the fan will deliver 1187 m3/h. The head of fan will be 416 Pa.
Example 3: The motor driving a fan is rated at a current of 15 A. During the energy audit the
current of 11 A was measured and the speed of the fan was 900 rpm. The airflow rate delivered by the
fan is to be increased as much as possible. What is the permissible speed of the fan within the rating
of the motor, and what percentage increase in airflow can be expected?
Solution:
By Eq. (10) one can find that speed of the fan can be increased up to:
rpm99811
15900
I
Inn 33
old
newoldnew
(8.30
)
The power of a three-phase electrical motor is cosIV3N LL . In the equation above it is
assumed that line voltage and cos are constant. The power of the electrical motor will increase by
36.4 % as compared to the present conditions for driving the fan.
Since flow rate is proportional to the fan’s speed, the percentage increase in flow rate is:
%9.10100900
900998100
V
VVV
old
oldnew (8.31
)
The fan’s speed can be increased, for example, by simply replacing the fan’s or electrical motor’s
pulley.
Example 4: A centrifugal pump feeds 50 m3/h of
water temperature 60 oC into the tank. The inner
diameter of the suction pipeline is 100 mm and its
length is 6 m. The friction factor is 0.028 and the sum
of loss obstacles is 2.5. The speed of the pump is 1450
rpm.
The suction head (height) has to be calculated
(Fig. 8.25).
PUMP
Pump shaft
FLOW
Hs
din
Figure 8.25: Pump Application
Part III – Toolbox 8:
PUMPS and FANS 21
Solution:
The velocity of water in the suction pipe is:
]s/m[768.1
4
1.0
3600
50
4
d
Vw
22s (8.32
)
The hydraulic resistance of the suction line including the energy needed for imparting a velocity to the
flow of liquid is as follows:
]m[8256.080665.92
768.1
1.0
6028.05.21
g2
w
d
L1h
22s
s,1 (8.33
)
The cavitation correction can be determined by using Eq. (13):
]mWC[2267.114503600
5000125.0nV00125.0h
67.0
267.02cav
(8.34
)
or, bar120.01080665.92267.1h 2cav .
The suction head of a centrifugal pump is calculated by using the following relation:
]m[11.62267.18256.00980665.0
19917.0
0980665.0
0.1hhhPH cavs,1satas
(8.35
)
where:
Pa = 1.0 bar (atmospheric pressure)
hsat = 0.19917 bar (saturated vapor pressure of the water at the pumping temperature – see
Toolbox III-4 (Eq. 4.6) or Software 5).
Example 5: The delivery factor of a gear pump has to be determined for a speed of 440 rpm.
The number of teeth on a gear wheel is 12, the width of a tooth is 42 mm, and the cross-sectional area
of a tooth restricted by the addendum circle of the mating gear wheel is 960 mm2. The actual flow rate
of the pump is 0.312 m3/min.
Solution:
The theoretical flow rate of the pump is:
]s/m[007096.060
44012042.000096.02V 3
(8.36
)
The actual (measured) flow rate is ]s/m[0052.060
312.0V 3
a . The delivery factor is now:
733.0007096.0
0052.0V
(8.37
)
Part III – Toolbox 8:
PUMPS and FANS 22
Example 6: The characteristics of a centrifugal fan are:
V m3/s 0 2 4 6 8 10 12
p Pa 165 170 170 160 135 110 55
- 0 0.36 0.49 0.51 0.44 0.32 0.16
This fan operates in a network defined by the following equation:
2
n V20p (8.38
)
Where:
V = Flow rate of air, [m3/s]
pn = Pressure losses in network, [Pa]
The comparison of power has to be analyzed for the following cases:
a) defined working point;
b) when speed of fan is reduced to meet the flow rate of 6 m3/s.;
c) when throttling is used to reduces the flow rate.;
d) when two fans are connected in line. The resulting flow rate has to be found.
Solution:
By fitting the values from fan characteristics given in the table above, the following analytical
equations are obtained:
3
234-2
101.64556 + V106.77489
+ V101.88920 - V1.46780 + V10-8.28598p
(8.39
)
-223-14-3 103.75190 - V7.32905+ V1.63695 - V101.99293 + V10-7.48625N (8.40
)
-3-12-23-4 106.66667 + V102.19623 + V102.76190 - V108.68056 (8.41
)
The table's values and values calculated from the above mentioned equations are presented in Fig.
8.26.
Part III – Toolbox 8:
PUMPS and FANS 23
0
300
600
900
1200
1500
1800
0 2 4 6 8 10 12 14
Flow rate [m3/s]
Head [P
a]
0
10
20
30
40
50
60
Pow
er
[kW
] and E
ffic
iency [%
]
Head
Power
Efficiency
Figure 8.26: Characteristics of Fan versus Flow Rate
a. The working point is defined as a cross-section of head curve and network curve (Fig. 8.27). The
following values are obtained at the working point:
Va = 8.25 m3/s
Ha = 1360 Pa
Na = 26.22 kW
a = 0.43
The power per unit flow rate is:
)]s/m/(kW[178.325.8
22.26
V
N 3
a
(8.42
)
The working point is presented in Fig. 27.
0
500
1000
1500
2000
2500
0 2 4 6 8 10 12
Flow rate [m3/s]
He
ad
an
d P
ressu
re lo
sse
s o
f n
etw
ork
[P
a]
Working point
V = 8.25 [m3/s]
H = 1360 [Pa]
Head
Network
Figure 8.27: Working Point for Case a
Part III – Toolbox 8:
PUMPS and FANS 24
b. In this case the flow rate of air is 6 m3/s. The network pressure drop curve is not changed. By
reducing the speed of the fan from na to nb the power of the fan will also be reduced. From Eqs
(8.9)–(8.11) the following relation can be obtained:
bb
aa
b
a
HV
HV
N
N (8.43
)
where subscripts a and b are related to two different speeds of fan. Comparing this relation to the fan
power relation (Eq. (8.5)), it is obvious that this relation is valid only if the efficiency for these two
speeds are the same ( 43.0ba ).
For flow rate 6 m3/s the pressure losses of network are:
]Pa[720620p 2b,n (8.44
)
The power of the fan for a reduced speed and flow rate is as follows:
]kW[05.1043.01000
7206Nb
(8.45
)
The power per unit flow rate in this case is:
)]s/m/(kW[675.100.6
05.10
V
N 3
b
(8.46
)
c. By throttling the flow without changing the speed of the fan, the new flow rate will be 6 m3/s. The
head and efficiency of the fan can be calculated by using analytical expressions. The results are:
Vc = 6.00 m3/s
Hc = 1582 Pa
Nc = 18.35 kW
c = 0.52
The power per unit flow rate in this case is:
)]s/m/(kW[058.300.6
35.18
V
N 3
c
(8.47
)
d. By connecting two fans in a line (serial connection), the head is doubled for the same flow rate
(Fig. 8.28). The working point in this case is as follows:
Vd = 11.66 m3/s
Hd = 2719 Pa
Nd = 2 40.42 = 80.82 kW
d = 0.19
Part III – Toolbox 8:
PUMPS and FANS 25
The power per unit flow rate in this case is:
)]s/m/(kW[933.666.11
42.402
V
N 3
d
(8.48
)
0
500
1000
1500
2000
2500
3000
3500
4000
0 2 4 6 8 10 12 14
Flow rate [m3/s]
He
ad
[P
a]
(a)(b)
(c)
(d)
Network
Head (one fan)
Head (two fans in line)
V = 8.25 [m3/s]
H = 1360 [Pa]
N = 26.22 kW
= 0.43
V = 11.66 [m3/s]
H = 2719 [Pa]
N = 80.82 kW
= 0.19
V = 6.00 [m3/s]
H = 1852 [Pa]
N = 18.35 kW
= 0.52
V = 6.00 [m3/s]
H = 720 [Pa]
N = 10.05 kW
= 0.43
Figure 8.28: Working Points for Case a, b, c and d
Comparing the results one can conclude that regulating flow by changing the speed of the fan is more
efficient than throttling the flow. The power per unit of flow rate is, in the first case, 1.675
[kW/(m3/s)] and, in the second, 3.058. By using two fans to increase the flow rate, the power per unit
flow rate is quite high (6.933). That means that some other solution has to be analyzed (for example,
increasing speed and replacing the electrical motor or replacing the fan).
References Chopey, N.P., Hicks, T.G. (Eds) (1984) Handbook of Chemical Engineering Calculations,
McGraw-Hill Book Co.
Elonka, S.M. (1980) Standard Plant Operators' Manual, McGraw-Hill.
Pavlov, K.F., Romankov, P.G., Noskov, A.A. (1979) Examples and Problems in the Course of Unit
Operations of Chemical Engineering, Moscow.
Stoecker, W.F., Jones, J.W. (1984) Refrigeration and Air Conditioning, McGraw-Hill.
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